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Electricity Network Access &
Forward Looking Charges: Final
Report and Conclusions
A Report by the Charging Futures Access &
Forward Looking Charges Task Forces
May 2018
3
1. Introduction and Background ...................................................................................... 5
Task Forces’ Final Report .................................................................................................. 5
Drivers for this Work – the Changing Energy System ........................................................ 5
Charging Futures Forum (CFF) ......................................................................................... 7
Baringa Materiality Assessment ......................................................................................... 8
2. Task Force Work-plan ................................................................................................ 9
Work-plan Background ...................................................................................................... 9
Stage 1: Initial Options Paper ............................................................................................ 9
Stage 2: Development of Framework Scenarios, Clusters and Assessment Methodology11
Framework Scenarios ...................................................................................................... 11
Stage 3: Assessment ....................................................................................................... 15
3. Assessment of Framework Scenarios ...................................................................... 16
Framework Scenarios ...................................................................................................... 16
Summary ......................................................................................................................... 19
4. Assessment of C1 – Influences User Investment ...................................................... 20
Four Cluster Combinations .............................................................................................. 20
Summary – User Investment Decisions ........................................................................... 26
5. Assessment of C2 – Influences User Operations ...................................................... 29
Four Cluster Combinations .............................................................................................. 29
Summary – Influencing User Operations ......................................................................... 39
6. Assessment of Tariff Design and Charging Methodology Options ............................ 42
Tariff Design .................................................................................................................... 42
Charging Methodology .................................................................................................... 48
Summary – Tariff Design and Charging Methodology ...................................................... 54
7. Access Properties .................................................................................................... 56
Access Building Blocks .................................................................................................... 56
Safeguarding for Domestic Users (Including Vulnerable Users) and Micro-businesses ... 58
8. Initial Allocation of Access ........................................................................................ 59
Initial Allocation ............................................................................................................... 59
Summary ......................................................................................................................... 62
9. Plausible Packages .................................................................................................. 64
Overview ......................................................................................................................... 64
Illustrative Examples ........................................................................................................ 64
Summary ......................................................................................................................... 74
10. Summary and Recommended Further Work ............................................................ 76
Report Section Summaries .............................................................................................. 76
Further Detailed Considerations ...................................................................................... 79
4
11. Glossary ................................................................................................................... 82
12. Appendices .............................................................................................................. 84
5
1. Introduction and Background 1.1 This section sets out background to the Charging Futures Forum (CFF) Access project
and describes: the key drivers behind the work of the CFF and its Task Forces; their
objectives; and the approach taken for carrying out work and delivering outputs. Other
relevant work that has been carried out in parallel to that of the Task Forces is also
highlighted.
Task Forces’ Final Report 1.2 This is the final report of the Access Task Force and Forward Looking Charges Task
Force established under the CFF.
1.3 In July 2017 Ofgem announced plans to establish the CFF to provide direction to
ongoing charging reviews and to develop an integrated work programme for these and
other elements of Ofgem’s work.
1.4 In November 2017 Ofgem published its ‘reform of electricity network access and
forward-looking charges: a working paper’1 which highlighted the need to review the
current regulatory framework in response to the rapidly changing energy system,
including the transition to a smart flexible energy system. Specifically, the working paper
identified the need to ensure that, as this transition progresses, the regulatory framework
remains fit for purpose. This includes ensuring that network capacity is allocated and
used in a way that minimises overall costs to users, part of which can be achieved by
providing network users with better signals about the costs and benefits they confer on
the network at a given time or location. As a first step in delivering these objectives, the
working paper points to the need to identify issues and key regulatory gaps that may
need to be addressed.
1.5 This final report builds on the Task Forces’ ‘initial options for change’2 paper published
in January 2018, and the ‘interim progress update’3 published in April 2018.
1.6 The overall purpose of this final report is to inform Ofgem’s assessment of the options
for reform of the current network access and charging arrangements. In preparing it the
Task Forces have sought to identify and outline options for change that have the
potential to create better future arrangements.
1.7 In compiling this report, the Task Forces have only considered the impact of changes
on the electricity networks. It is recognised that a whole system approach will ultimately
be needed to fully appreciate the impact on the energy system as a whole. In looking at
these costs in isolation, the Task Forces have intentionally only considered network
impacts, with wider system impacts being a matter for further consideration elsewhere.
Drivers for this Work – the Changing Energy System 1.8 Great Britain has seen a rapid change in the way in which energy is produced, with
growth in distributed and locally connected energy resources. At the same time the take
up of new technologies and solutions such as behind the meter generation, electric
vehicles, electric heating, smart meters and energy storage is increasing, and users are
1 https://www.ofgem.gov.uk/publications-and-updates/reform-electricity-network-access-and-forward-looking-charges-working-paper 2 http://www.chargingfutures.com/media/1130/access-and-flc-options-paper-final-published-12022018.pdf 3 http://www.chargingfutures.com/media/1188/interim-progress-report-overview.pdf
6
seeing greater choice and control over the way in which they use energy. These changes
could lead to significant increases in peak demand and create constraints on some parts
of the electricity network. Network reinforcement to address constraints can be costly,
time consuming and disruptive, and could therefore present a barrier to the take-up of
new technologies and changing patterns of usage.
1.9 The pace of change can be expected to hasten over the next decade and beyond,
bringing unprecedented challenges in the way in which electricity networks are
designed, operated and managed. By extension this also points to the need for change
in the commercial, regulatory and technical arrangements that govern the way in which
different users (for example domestic households (including vulnerable users); large and
small generators; and large and small commercial demand users) connect to and utilise
the electricity networks.
1.10 It is crucial that networks continue to meet the needs of all users, and continue to be
managed in a way that is in the interests of current and future users. Central to this is
ensuring that current network capacity is most effectively and efficiently utilised and that
appropriate economically efficient signals indicate where there is need for new
investment in networks, including traditional reinforcements. Put simply, it is increasingly
important that the use of network capacity is managed over all timescales in a way which
minimises the costs to users as a whole.
1.11 The emergence of smart technologies for smaller users that offer greater digitisation,
visibility and control of the electricity networks together with new and innovative business
models offer opportunities to adjust demand and supply at times and places where there
are network constraints. This smart approach is already being used for users connected
to the transmission network and it could deliver greater system benefits if these types of
approaches were extended to users connected to the distribution networks as well, by
potentially deferring or reducing the network reinforcement needed. If the way in which
network capacity is allocated and utilised is to be optimised so as to minimise costs to
users, not only is it necessary to explore different approaches and the models which
govern those approaches, but also to ensure there is a level playing field for all network
users. This means identifying and addressing issues and distortions that exist between
and across the transmission and distribution networks which have the potential to affect
investment and operational decisions by those already connected to the electricity
system as well as those seeking to connect.
1.12 Ofgem’s ‘strategy for regulating the future energy system’4 set out its approach to
regulation over the coming years in the context of the energy system transformation and
current priority actions to address the key challenges and opportunities that future
changes could create for different aspects of the energy market and regulatory
arrangements. Ofgem also published its ‘smart systems and flexibility plan’5 (joint with
Government) to enable the development of a smart, flexible energy system that will
reduce costs for users, and support the growth of innovative new businesses. Both of
these documents describe how providing users with better signals about the costs and
benefits they confer on the network at a particular time and place is a priority area to
address.
4 https://www.ofgem.gov.uk/publications-and-updates/our-strategy-regulating-future-energy-system 5 https://www.ofgem.gov.uk/publications-and-updates/upgrading-our-energy-system-smart-systems-and-flexibility-plan
7
Charging Futures Forum (CFF) 1.13 The CFF is chaired by Ofgem and is open to network users, network companies and
end users and/or their representatives. The CFF has a central role in keeping
stakeholders up-to-date on developing network charging reform and gives them the
opportunity to influence works being undertaken. The role of the CFF includes:
enabling stakeholders to provide policy input and technical expertise for policy
developments which are in the scope of the arrangements;
keeping stakeholders informed about progress of the various work areas; and
setting up Task Forces to develop and evaluate potential options for change.
1.14 Further information on the CFF, the Task Forces and work being undertaken can be
found on the charging futures website6.
1.15 Under the CFF, two Task Forces (the Access Task Force and Forward Looking Charges
Task Force) were established to assist in the policy development process. The
objectives of these Task Forces were to consider what changes could be taken forward,
in each policy area, in order to drive benefits to users through supporting more efficient
use and development of network capacity. The Task Forces’ work has been informed
by Ofgem’s working paper (see paragraph 1.4) and has identified and assessed options
that may create better arrangements.
1.16 Membership of the Task Forces includes a wide range of stakeholders. Their work
includes a programme of ongoing engagement with wider stakeholders and interested
parties, particularly through the CFF.
1.17 The Task Forces bring together a range of expertise and interests from across the
energy industry and wider stakeholder communities. The working approach adopted by
the Task Forces has been to use regular meetings as a forum to agree, review and
discuss the work of the group and its outputs. Consistent with this approach, work has
been taken forward by a subgroup of Task Force members in a collaborative working
group format.
1.18 The Access Task Force has considered the options to define more explicitly potential
arrangements for user access to the GB electricity system (transmission and
distribution). The Forward Looking Charges Task Force has considered the options for
the improvement of the forward looking elements of network charging (i.e. those
elements that provide a signal to users about how their behaviours can increase or
reduce future costs on the network and as a result the charges they receive). This report
is the final report of both Task Forces, with the work of the two having been combined
into a single output.
1.19 Residual network charges (i.e. those elements of network charges that are not defined
as forward looking) have not been included within the scope of the Task Forces. This is
because the application of residual network charges is being progressed by Ofgem as
a separate project under a Significant Code Review (SCR), known as the Targeted
Charging Review (TCR). More information is available on the TCR on Ofgem’s website7.
6 http://www.chargingfutures.com/ 7 https://www.ofgem.gov.uk/electricity/transmission-networks/charging/targeted-charging-review-significant-code-review
8
1.20 The outputs from the Task Forces will inform Ofgem’s thinking ahead of its consultation
on initial proposals for reform of network access and forward looking charging
arrangements (if any), which is expected in summer 2018. The terms of reference for
the Task Forces together with their membership can be found on the charging futures
website8.
1.21 The Task Forces had three major deliverables, namely to:
produce a document identifying the initial options agreed for further assessment
in December 2017/January 2018;
produce a document assessing each of the initial options, based on the agreed
assessment criteria in February/March 2018; and
produce a report outlining the Task Forces’ conclusions on what changes could
be taken forward for further consideration in April/May 2018.
1.22 The terms of reference of the Task Forces were ambitious. Its members have embraced
this and committed significant time towards achieving them. However, it is important to
note that the breadth of the work and the relatively limited time during which the Task
Forces have met to finalise their conclusions necessarily means that the Task Forces
have not been able to address all aspects comprehensively. The Task Forces’ work
should be considered the start of discussions on reforming network charging regimes,
not the final word.
1.23 This final report by the Access and Forward Looking Charges Task Forces constitutes
the final deliverable of these outputs. Following the conclusion of this report, the Task
Forces will cease to exist. Feedback on this report is welcomed through the CFF.
Baringa Materiality Assessment 1.24 Baringa has been commissioned by Ofgem to develop an analytical framework for the
assessment of the materiality of issues with existing arrangements for network access
and forward looking charges. The work will highlight issues resulting from the current
arrangements and will identify areas impacted by the current arrangements and the
types of impact. Baringa’s assessment of impacts will be conducted with a qualitative
approach, with supportive estimates and quantitative data being provided where
possible. At the time of the Task Forces finalising this report, Baringa have yet to publish
their assessment.
8 http://www.chargingfutures.com/media/1108/final-cff-tf-tor_12jan18.pdf
9
2. Task Force Work-plan 2.1 This section describes the work undertaken by the Task Forces in developing the first
two phases of the work-plan as detailed in paragraph 1.21.
Work-plan Background 2.2 The work-plan (shown in Appendix One) details the key activities, outputs and
associated timelines of the work of the Task Forces since they were established in
September 2017.
2.3 Task Force activity over the period was intensive with each of the Access and Forward
Looking Task Forces meeting seven times, four of which were joint meetings. Output
from the Task Forces was disseminated through the CFF website and mailing list;
several meetings of the CFF; and targeted events including CFF workshops held in
London and Glasgow.
Stage 1: Initial Options Paper 2.4 The main stage one output of the Task Forces was the ‘initial options for change’ paper
published in January 2018. It sought to complement Ofgem’s working paper on the
reform of network access and forward looking charges and the issues and options for
reform identified within it, including how capacity might be allocated and reallocated and
where cross-system changes to the charging methods could be beneficial.
2.5 The initial options paper was broadly in two parts:
Part one focused on access and considered a number of aspects of users’
access to the GB electricity system. This included the identification of different
building blocks that could be used in determining and defining various access
arrangements for users. The question of initial allocation of access (i.e. the way in
which a new user connects to the network) was also considered with various
approaches identified for the initial allocation of access rights to users, including
the desirable features of particular approaches. Options for reallocation and
trading of access rights were also explored.
Part two focused on forward looking charges and considered options relevant
to the application of forward looking signals through charging arrangements.
Aspects covered included: locational and temporal signals (i.e. how charges differ
by the location of use and time of use to reflect the state of the network and
encourage use of the network where and when it is most efficient); the options for
structuring forward looking charges to provide signals to users about their
behaviours and impact on future network costs; and the factors that might be taken
into account in the design of different approaches. It also identified a number of
options for the structure of forward looking charges.
2.6 Whilst not exhaustive, the options captured in the paper represented a significant
number and range of approaches, each having different benefits, advantages or
disadvantages.
2.7 Finally, the initial options paper recommended a number of assessment criteria,
informed by the desirable characteristics for access and forward looking charging
arrangements identified by Ofgem in its working paper. These criteria are set out below
10
and were used to guide the assessment stage of this work, the results of which are set
out under sections 3 to 6 of this final report.
Assessment Criteria
2.8 The agreed assessment criteria are that arrangements should:
1. efficiently meet the essential service requirements of network users;
2. optimise capacity allocation;
3. ensure that price signals reflect the incremental future network costs and benefits
that can be allocated to and influenced by the actions of network users;
4. provide a level playing field for all network users;
5. provide effective network user price signals, i.e. price signals which can be
reasonably anticipated by a user with sufficient confidence to allow them to take
action;
6. appropriately allocate risk between individual network users and the wider body of
users;
7. support efficient network development;
8. be practical; and
9. be proportionate.
Definition of Building Block, Option & Cluster
2.9 The terms ‘building block’, ‘cluster’, ‘option’ and ‘scenario’ are used throughout this
report, each of which are described below. These are essential temporal, physical or
commercial/regulatory features of the arrangements under which a user will connect to
and utilise the electricity network.
Building block: a key design parameter in the make-up of access or charging
arrangements. Building blocks can be used to outline the key different possible
choices for how network access rights and forward looking network charges could
theoretically be constructed. Examples of building blocks include depth of access
(e.g. access to the whole network, or access to only certain voltage levels);
lifespan of access (i.e. the number of years for which a user has access); firmness
of access (i.e. how physically secure the connection is and whether users are
compensated if the network is unavailable, due to, for example, a network
constraint); connection charging boundary (i.e. how much of the reinforcement
triggered by a new connectee is paid for in a connection charge, and how much is
paid for through ongoing usage charges); timing of payment of connection charge;
and types of locational signal. Building blocks can co-exist and are not mutually
exclusive.
Option: a possible aspect of a building block of a new access or charging regime
that can be picked at its most granular level. For example options for a new regime
under the ‘connection charging boundary’ building block are either shallow (i.e.
extension assets only), ‘shallowish’ (i.e. extension assets and a proportion of wider
network reinforcements required) or deep (i.e. cost of all associated reinforcement
across the entire wider network). Within a building block the options tend to be
mutually exclusive alternatives, albeit different options under a given building block
could be used in parallel for different users, or different options used for
transmission and distribution respectively.
11
Cluster: a combination of ‘building blocks’ that are naturally linked such that it is
helpful to consider them together rather than in isolation. For example, the
respective advantages and disadvantages of paying connection charges up front
compared with being annuitised depends on whether the connection charging
boundary is deep or shallow, because this would affect the likely magnitude of the
connection charge. Not all building blocks naturally fall into clusters. For example,
there are a number of other aspects of any access and charging regime that also
need to be considered including: modelling and tariff design; the structure of
charges; and market based approaches that could possibly be used to apply
targeted approaches for the allocation of access to and utilisation of the electricity
system. These are considered in isolation as individual building blocks.
Scenario: a set of arrangements which describes a complete solution to how
users would access the electricity network, and how they would be charged for
doing so. Scenarios have generally been described at a very high level, and used
as tools to enable the Task Forces to consider how different arrangements could
impact different users. Section 9 discusses some scenarios in more detail, by
bringing together the various clusters and building blocks into ‘plausible
packages’.
Stage 2: Development of Framework Scenarios, Clusters and
Assessment Methodology 2.10 To help bring a ‘real world’ aspect to this work a number of framework scenarios were
developed. These framework scenarios were found useful both in the development of
the clusters and when considering questions of implementation of different options and
the needs and limitation of different network users (user segmentation).
2.11 The Task Forces then took the outputs contained in the ‘initial options for change’ paper,
developing them further and bringing them together into a number of combinations or
‘clusters’, each creating a particular set of conditions that could apply to system users,
and so drive particular types of behaviour.
2.12 This left a number of building blocks not considered in the clusters, which were
considered in isolation as they did not naturally fall into a cluster.
2.13 These different scenarios, clusters and remaining individual building blocks were then
analysed and assessed against the nine criteria set out under paragraph 2.8. The
approach followed for the assessment is described in more detail below.
Framework Scenarios 2.14 Three framework scenarios were developed and used to help the Task Forces
appreciate the advantages and disadvantages of different options by considering each
at its most extreme. The framework scenarios are shown in Figure 1:
12
Figure 1 - Three Framework Scenarios
2.15 The first scenario (high emphasis on auctions/trading) focusses on an approach for the
allocation and reallocation of access rights, the second (high emphasis on access right
choices) focusses on providing user choice with regard to which access product is
suitable for a users’ needs, whilst the third (high emphasis on better usage charges)
relies on cost signals through ongoing usage charges to drive the efficient utilisation of
capacity. A more detailed description of the three scenarios and the results of their
evaluation are set out under section 3.
Development and Grouping of Options
2.16 The initial options paper included 18 building blocks with 56 associated options. The
high level framework scenarios discussed above cover some but not all of these building
blocks, hence a lower level analysis is required. Given the number of options involved,
it is not feasible to assess every combination. A number of the building blocks were
therefore grouped into two clusters, while the remainder of the building blocks were
evaluated individually.
2.17 Cluster one (C1) comprises those building blocks which influence user investment (both
new connections users and those already connected). These building blocks are not
mutually exclusive and hybrid options may exist. For simplicity, hybrid options have not
been considered at this stage. Each of the building blocks considered here is defined in
more detail in the initial options paper. The building blocks considered are:
Connection charging boundary (shallow, ‘shallowish’, or deep);
Timing of payment of connection charge (unsecured annuity, secured annuity,
or paid upfront, i.e. whether users are required to place a form of deposit for a
connection charge paid over a number of years);
Locational granularity of ongoing charges (none, some (e.g. zonal, i.e. relating
to a group of nodes), or high (e.g. nodal, i.e. relating to the point where a specific
user connects)); and
Degree of user commitment (i.e. the financial liability on connectees) to wider
reinforcement (none, securitised until connected, or securitised after connection,
i.e. whether users are required to place a form of deposit or not).
13
2.18 These four building blocks are inherently interlinked. This is because, when making an
investment decision, a user would be expected to consider the liabilities they are taking
on as part of that decision, which would include the initial connection charge, the ongoing
charges that user will face (including any annuitisation of the connection charge and
ongoing usage charges) and any other securities required up to and after the point of
connection.
2.19 Figure 2 shows how these elements are grouped together under C1:
Figure 2 – Tree diagram of C1
2.20 Cluster two (C2) comprises those building blocks which influence users’ operational
decisions. This may be through the ongoing usage charges that apply or mechanisms
for reallocating existing capacity. These building blocks are not mutually exclusive and
hybrid options may exist. For simplicity, hybrid options have not been considered at this
stage. Each of the building blocks considered here is defined in more detail in the initial
options paper. The building blocks considered are:
Short-term reallocation (none, bilateral trading (i.e. trading between two parties,
possibly facilitated by a third party), or an extension of the Balancing Mechanism);
Medium-term to long-term reallocation (none, bilateral trading, or market
trading);
Temporal signals (none, average/static (e.g. averaged across time such as
day/night) or granular/dynamic (e.g. granular Settlement Periods)); and
Locational granularity of temporal signals (none, zonal (averaged across
locations) or nodal (granular)).
2.21 These four building blocks are inherently interlinked. This is because, when making an
operational decision, a user would be expected to consider all of the costs and benefits
associated with that decision, whether those costs and benefits are derived from ‘selling’
their access rights to other users or into a market, or costs and benefits derived from
time of use signals.
14
2.22 Figure 3 shows a ‘tree diagram’ representation of C2:
Figure 3 - Tree diagram of C2
Cluster Options Selected for Assessment
2.23 Given the high number of possible cluster options (81 possible combinations for each
cluster) the Task Forces focused on a number of cluster combinations that combined to
form mutually reinforcing combinations of options in order to provide a representative
range of different approaches. A total of four C1 cluster combinations and five C2 cluster
combinations were chosen for further analysis and assessment. These are detailed in
sections 4 and 5 respectively.
Other Building Blocks
2.24 Other building blocks do not naturally fit into a cluster so are dealt with in their own right.
These are:
tariff design and charging models (see section 6);
properties of access rights (partially covered by the framework scenarios, and
further in section 7); and
initial allocation of access rights (partially covered by the framework scenarios,
and further in section 8).
Assessment Methodology
2.25 To assist in the assessment of options against the assessment criteria (as detailed in
paragraph 2.8), the assessment criteria were aligned with their associated Connection
and Use of System Code (CUSC) and Distribution Connection and Use of System
Agreement (DCUSA) applicable objectives. Details of this grouping can be found in
Appendix Two.
2.26 The Task Forces considered the merits of a quantitative (i.e. ranking) versus qualitative
(i.e. pros and cons) approach to assessing each option against the assessment criteria.
Some Task Force members felt that a quantitative approach could aid the Task Forces
in reaching conclusions and create an argument for a set of proposed arrangements
better facilitating the applicable code objectives (as scoring would be carried out against
the baseline); whilst others felt that a scoring approach could be overly complex in the
time available and risk becoming a distraction. The qualitative approach was ultimately
progressed.
15
2.27 A number of approaches were developed and applied in order to carry out the qualitative
assessment stage of the work.
All Task Force members were asked to describe their view of the advantages and
disadvantages of each of the scenarios, clusters and individual building blocks
against the nine assessment criteria. The results of the assessments were
captured in a number of Excel workbooks. This ensured that a range of user
perspectives were captured within the assessment.
Task Force meetings were used to enable a collective assessment to be carried
out. This generally took the form of subject matter overview presentations followed
by break-out sessions, discussions and feedback.
Throughout the work programme and in the production of outputs, including
reports, individual Task Force members were provided the opportunity to review
and provide feedback and input to the work.
2.28 All feedback received through these various approaches was captured and incorporated
into the assessments.
2.29 The results of the assessments are summarised in the following sections. The full results
of the assessments are available in Appendix Three (framework scenarios), Appendix
Four (C1), Appendix Five (C2), Appendix Six (tariff design) and Appendix Seven
(charging models).
Stage 3: Assessment 2.30 The remaining sections of this report describe the third stage of the Task Force work
involving the assessment of the options which had been identified.
16
3. Assessment of Framework Scenarios 3.1 This section summarises the views of Task Force members on the advantages and
disadvantages of the three framework scenarios when considered in the context of the
nine assessment criteria. The full views provided can be found in Appendix Three.
Framework Scenarios 3.2 The Task Forces initially considered three high level scenarios, as detailed in paragraph
2.14, namely:
high emphasis on auctions/trading;
high emphasis on access right choices; and
high emphasis on better usage charges.
High Emphasis on Auctions/Trading
Advantages as expressed by Task Force members
Optimising capacity allocation:
o Could optimise allocation behind a constraint
(e.g. targeted auctions for local constraints).
This would depend on the ‘product’ being
auctioned (e.g. auctioning access rights for a
Settlement Period would give a very different
outcome to auctioning evergreen (i.e. without
a finite lifespan) access rights).
o May create a market in which suppliers or
aggregators compete to create portfolios
which optimise allocation.
Providing effective network user price signals:
o An auction taking place behind a constraint reveals the value of network
access at a given location.
Disadvantages as expressed by Task Force members
Creating a level playing field:
o There are challenges in safeguarding smaller users, which then risk creating
the potential for gaming across boundaries.
o Capacity is allocated at ‘value’ rather than ‘cost’ as it is now – those with the
deepest pockets will always win.
Appropriate allocation of risk:
o If access for smaller users is protected, this would place disproportionate
risk on larger users. There is a potential parallel with current micro-
generation assigned ‘rights’ compared to larger generation which is required
to apply for ‘access’.
Cost-reflectivity:
o Prices would reflect the value to users rather than the cost of the network.
This may result in extremely expensive clearing prices equivalent to the
entire value of the user’s underlying business. For example, if particular
users failed to secure access to the network, then a renewable generator
could not generate, a factory could not operate, while hospitals and schools
may have to close.
Support efficient network development
17
o Auctions provide a poor price signal for network investment. Network
companies may have poor visibility of the current and future bid stack, so it
will be very difficult for network companies to predict what the impact of a
given network investment will be on future auction clearing prices.
Practicality and proportionality:
o Barriers to creating a level playing field are mitigated if more users
participate in an auction, but an auction for a large number of users will be
difficult to administer.
o This is a revolution from the status quo which would represent significant
legal issues (for those already connected) as well as practical and financial
barriers to set-up for new users. The benefits of this option would need to be
beyond doubt in order to satisfy investor confidence.
o An auction in itself could create the perception of the possibility of non-
access as an outcome. This could be seen by developers as an additional
barrier to developing their projects.
o An auction requires a specified capacity of network to sell. There is no fixed
availability of network capacity. Firstly, if demand exceeds existing network
capacity, then additional network capacity can be built. Secondly there is
circularity because the network capacity available to be auctioned depends
on the level of sharing and the particular mix of users across the network
which in turn would depend on the result of the auction, which is not known
in advance.
o The amount of capacity allocated to smaller users is not clear under present
arrangements as the majority of small users do not have an agreed capacity.
This would need to be clarified to enable auction participation.
o It could potentially be difficult for network companies to enforce capacity
constraints on unsuccessful bidders, without resorting to de-energisation.
o Auctions fail to address the key issues which the Task Force was set up to
consider. If one of the biggest identified issues with current arrangements
relates to increasing congestion on distribution networks causing a need to
provide more efficient price signals to smaller users and demand (including
behind the meter generation, demand side response and electric vehicles),
then it is this very group for which auctions are least appropriate and least
effective.
High Emphasis on Access Right Choices
Advantages as expressed by Task Force members
Providing effective price signals, and appropriately
allocating risk:
o Creates a clear, upfront price signal to which
users can respond (either by changing e.g.
time of use if already connected, or
connecting elsewhere if not).
o Clearly designed products enable users to
know what risk they are taking upfront.
Supporting efficient network development:
o Network companies have visibility (potentially
many years in advance) of the access rights
users have requested, and so can develop
networks accordingly.
18
Disadvantages as expressed by Task Force members
Cost-reflectivity:
o Risks over-valuing ‘access’ and under-valuing ongoing behavioural
changes.
Practicality:
o Creates a potential need for significantly more detailed Connection
Agreements for larger users (detailing e.g. time of access at given levels).
o The requirement to much more closely define access rights for smaller users
could be challenging.
o Users may purchase or lease properties with lower access rights than
expected or needed.
High Emphasis on Usage Charges
Advantages as expressed by Task Force members
Cost-reflectivity:
o Assuming the calculation of charges is done
on a sound basis, charges should accurately
reflect costs and benefits which can be
allocated to the behaviour of certain users.
Creating a level playing field:
o Each user should face the same charges (for
an equivalent unit of energy, i.e. at the same
time and location).
Disadvantages as expressed by Task Force members
Optimising capacity allocation:
o Potential for conflict between time of use
signals and other cost signals (e.g. the Balancing Mechanism).
o No improvement on ‘implicit’ sharing of capacity (i.e. how far a network
company makes use of users’ different patterns of usage to achieve optimal
network usage) which exists under the status quo (unless a greater
emphasis were put on capacity charging applied to all user types).
o There are practical difficulties with creating granular locational prices at low
voltage (LV) and high voltage (HV), meaning that some degree of
socialisation (i.e. costs shared across a wider body of users) will be retained.
Socialised or average tariffs could drive inefficient behaviour in some areas
and conflict with the effective allocation of capacity.
Providing effective price signals which can be predicted with confidence to take
action:
o There is a trade-off between time of use prices being effective which users
can respond to compared with time of use prices being cost-reflective. This
is because, in order to best facilitate user responses, time of use prices
should tend to be static (i.e. fixed) and set in advance, however this would
not be particularly cost-reflective. By contrast, for time of use prices to be
most cost-reflective, they would need to be dynamic (i.e. change as network
conditions change) at high granularity, which would likely result in a volatile
signal which may be difficult to predict and therefore respond to for network
users. Banded time of use charges (i.e. across several half hour periods)
could help to mitigate this until the system is ‘smart’ enough to work real-
time.
19
o Tariffs calculated at high locational granularity could be heavily influenced
by the actions of other users on the local network over which a user has no
control (i.e. a user could face higher charges despite having made the ‘right’
usage changes due to the actions of their ‘neighbours’ on the network).
o Uncertainty on network charges increases investment costs.
Cost-reflectivity:
o Network investment is generally driven by changes in user capacity
requirements, not changes in user profile use - if a user happens to increase
or reduce their use at a key time in one particular year (and therefore reduce
their time of use network charges in that year), this does not necessarily
reflect the cost of network that the network company needs to build to serve
that user in that, or future years.
Support efficient network development:
o Without contracted access rights, network companies would have relatively
poor visibility of the future demands on the network.
o Network companies would have relatively little control over the operation of
the network because it would be difficult for them to predict how users at
different locations would respond to particular price signals at a particular
time.
Summary 3.3 The analysis of the three framework scenarios identified a range of advantages and
disadvantages with the different approaches under consideration. However, the Task
Forces recognised that many of the options considered cut across the scenarios and
may have a different impact on individual users.
3.4 The framework scenarios describe potential future arrangements at a very high level.
Consequently it is difficult to draw conclusions from the consideration of these
framework scenarios without defining arrangements in more detail. The subsequent
sections seek to add this further level of detail.
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4. Assessment of C1 – Influences User Investment 4.1 This section summarises the views of Task Force members on the advantages and
disadvantages of four C1 cluster combinations when considered in the context of the
nine assessment criteria. The building blocks which define C1 are described in detail in
paragraph 2.17. The full views provided can be found in Appendix Four.
Four Cluster Combinations 4.2 Under C1, four cluster combinations have been considered. The first two of these
combinations represent options which are broadly consistent with existing arrangements
in use at transmission and distribution respectively, with a further two different options.
The options considered are:
C1-A – shallow connection charging with user commitment;
C1-B – shallowish connection charging with upfront capital payment;
C1-C – deep connection charging with upfront capital payment; and
C1-D – shallow connection charging with focus on strong ongoing usage signals.
4.3 Each of these cluster combinations is considered in the subsequent sections.
C1-A – Shallow Connection Charging with User Commitment
Description
4.4 This approach is broadly similar to existing arrangements at transmission level. Figure
4 represents the options selected under each building block to define cluster
combination C1-A.
Figure 4 - C1-A shallow connection charging with user commitment
4.5 The features considered under this cluster combination include the following:
Shallow connection boundary – the connection charge reflects the cost of
extension assets only (i.e. those assets needed to connect the new connectee to
the existing network). The cost of assets beyond extension assets is reflected in
ongoing usage charges.
The connection charge is paid on an annual basis. The new connectee is required
to provide user commitment for the period that the connection charge is
outstanding.
The ongoing usage charges include locational signals that broadly reflect the
regional drivers of investment costs which are set zonally, i.e. nodes (being points
on the network where individual users connect to the wider network) are grouped
21
into zones with similar properties, with the same locational signal being applied to
all nodes within a zone.
The new connectee is required to provide user commitment for wider network
investment until connected.
Advantages as expressed by Task Force members
Zonal charges can be easier to understand (than more granular nodal charges)
and can provide strong locational signals subject to appropriate zone size.
Lack of large upfront connection charges may help smaller players.
A move towards shallow connection charges should provide enduring price signals
to reduce usage of the network (through ongoing usage charges) where the usage
charges (instead of the sunk cost of upfront connection charges) are sufficiently
granular.
Network companies will see a clear incentive to assess alternatives to traditional
reinforcements.
Shallow connection charges can encourage trading or constraint management
systems and the development of Distribution System Operator models.
If implemented, this option would increase consistency across transmission and
distribution.
This option should be practical and easy to administer for larger users, albeit
transitional arrangement could be challenging for distribution connected users who
have already paid shallowish connection charges.
Disadvantages as expressed by Task Force members
Limited locational signals (for type of connection) to new connectees (shallow
connection charging boundary) with weaker penalty for overstating initial
requirements post connection.
Uncertainty over the level and volatility of future locational ongoing usage charges
for users who are already connected to the network.
If charging models rely on confidential user data, this may create transparency
issues (with charging models which cannot be published) and so increase
uncertainty for connected users.
An appropriate level of zonal pricing that avoids excessive socialisation of
connection costs may not be practical or feasible at lower voltage levels. The level
of zonal pricing would need to be very granular under a shallow connection policy
to ensure new connectees pay their fair share of the cost of connecting to the
network via the ongoing usage charges applied. Applying highly granular
locational charging at LV or HV has significant issues that need to be addressed,
namely the practicality of implementation (as it would require network companies
to maintain powerflow models of their LV and HV networks) and the potential for
a postcode lottery (e.g. with rural users potentially facing a substantial increase in
their network charges).
Limited user commitment (only until the point of connection and not beyond) could
increase risk of network asset stranding (i.e. where a network asset is built and
only used for a short period of time), the cost of which would inevitably be borne
by the wider body of users. The risk of stranding is, however, significantly reduced
by the requirement for user commitment until connection, and can be further
mitigated by effective communication and use of Connection Agreement
milestones so that the network company does not build assets where a developer
is not also progressing.
22
User commitment is potentially burdensome to administer at lower voltages due
to the high volume of users.
This could have the effect of essentially shifting charges from developers to end
users (an example being a new housing development) and removing any incentive
on developers to accurately specify capacity requirements commensurate with
future needs. Ultimately it could lead to cheaper construction costs with higher
energy bills.
Current arrangements at transmission require commitment from the user in the
form of securities for local and wider reinforcement works required for their
connections which can act as a barrier to more remote connections (e.g. island
connections).
Implementation could be complicated by dealing with legacy users (i.e. users with
existing connections on current terms – everyone who is currently connected or
has an existing Connection Agreement) or having a split charging arrangement.
C1-B – Shallowish Connection Charging with Upfront Capital Payment
Description
4.6 This approach is broadly similar to existing arrangements at distribution level. Figure 5
represents the options selected under each building block to define cluster combination
C1-B.
Figure 5 - C1-B shallowish connection charging with upfront capital payment
4.7 The features considered under this cluster combination include the following:
Shallowish connection boundary – assets paid on the following basis:
o Extension assets (i.e. assets required to connect the new connectee to the
existing network) – paid for in full by the new connectee.
o Reinforcement assets (i.e. existing network assets which require work in
order to accommodate the new connectee) – in most circumstances
apportioned between the new connectee and the wider body of users on a
capacity basis.
The connection charge is paid in full in advance of connection.
The ongoing usage charges include limited (or no) locational signals to influence
behaviour.
There is no user commitment requirement for wider network investment regardless
of whether the new connectee has contributed or not.
Advantages as expressed by Task Force members
Upfront charges encourage locating demand and/or generation where capacity is
already available.
23
Shallowish charges ensure the new connectee contributes some upfront costs of
connection, reducing the risk of stranded assets (which can also be mitigated by
effective communication and use of Connection Agreement milestones so that the
network company does not build assets where a developer is not also
progressing).
A move to shallowish charges for new transmission connectees would vary the
risk allocation and reduce uncontrollable risk to users of future tariff increases.
Minimal change for the majority of users.
This option allows for lower granularity of locational charges, which may make it
more feasible to implement at lower voltages.
High connection costs in constrained areas incentivise network companies and
prospective connectees to develop more efficient solutions to the benefit of all
users.
If implemented, this option would increase consistency across transmission and
distribution.
In the case where developers are connecting but are not the end user, shallowish
connection charging provides an investment cost signal to the party able to control
investment behaviour (i.e. the developer rather than end user).
Disadvantages as expressed by Task Force members
The obligation to pay upfront creates a barrier to connection and does not deal
with the existing issues of queues of new users in constrained areas.
Relatively weak ongoing price signals limit the network company’s ability to
influence user behaviours and increases costs of network management by
encouraging high-cost investment rather than potentially cheaper flexibility.
Lack of ongoing locational signal could result in inefficient use of the network and
higher costs to end users.
Shallowish connection charging boundary makes it difficult to integrate flexibility
and compensated connect and manage regimes. There may be implications for
the Balancing Mechanism of a move to deeper connection charges.
Connection charges can become prohibitively high in constrained areas. This is
unfair for new and future users and can encourage earlier connectees to use up
spare capacity to avoid higher connection charges.
A shallowish boundary without user commitment can leave other network users
exposed to the costs of new/augmented requirements or the costs of asset
stranding (although not to the extent seen under a shallow connection policy).
Requires a complex connection charging methodology, which is well established
at distribution level but would require significant development at transmission.
This approach socialises deeper connection costs which are more likely to benefit
many user and therefore should not be fully paid by a new connectee.
24
C1-C – Deep Connection Charging with Upfront Capital Payment
Description
4.8 This approach is broadly similar to the arrangements that existed for distribution
connected generation prior to 2005. Figure 6 represents the options selected under each
building block to define cluster combination C1-C.
Figure 6 - C1-C Deep connection charging with upfront capital payment
4.9 The features considered under this cluster combination include the following:
Deep connection charging boundary – the new connectee pays for all assets
required to provide the connection, including the full extent of any necessary
network reinforcement (network reinforcement being reasonably attributed to the
new connectee to avoid undue depth of charging or excessive user commitment).
The connection charge is paid in full in advance of connection.
The ongoing usage charges include limited (or no) locational signals to influence
behaviour.
There is no user commitment requirement for wider network investment.
Advantages as expressed by Task Force members
A strong upfront locational signal means that entire cost of connection rests with
the new connectee.
Enables new connectees to make clear decisions on the basis of the cost of
connection.
Removes uncertainty associated with future (and potentially volatile) ongoing
usage charges.
Protects existing users from risk related to new connectees.
Costs of stranded assets less likely to fall on the wider body of users.
Incentivises prospective connectees to seek flexible alternatives.
Simple to implement for the majority of users.
Gives a clear signal upfront (especially for larger sites) at the time of connection.
In the case where a developer pays the connection charge and an end user
becomes liable for the ongoing usage charges, deeper connection charges ensure
the locational signal goes to the party able to control it (i.e. the developer).
Disadvantages as expressed by Task Force members
Strong upfront signal in isolation makes reallocation of capacity difficult and may
encourage capacity hoarding (unless effectively mitigated through, for example,
use it or lose it rules), which disadvantages large demand and smaller users and
community groups, may encourage off-grid solutions and could stall further
network development.
25
Connection charges can become high in constrained areas. Deep connection
charges place excessive risk of reinforcement on individual users, and may result
in parties paying for reinforcement never used.
No forward looking price signals to encourage behaviours post connection would
result in a lack of incentive to be flexible.
Technology which can reduce constraints/network costs would have less incentive
to connect.
Increases cost of the Capacity Market.
Transition challenging.
C1-D – Shallow Connection Charging with Focus on Strong Locational Ongoing
Usage Signals
Description
4.10 C1-D is in many ways similar to C1-A, but with more granular locational ongoing usage
charges, meaning that specific costs associated with a given new connectee can be
reflected back onto that connectee through ongoing usage charges. Figure 7 represents
the options selected under each building block to define cluster combination C1-D.
Figure 7 – C1-D shallow connection charging with focus on strong locational ongoing usage
signals
4.11 The features considered under this cluster combination include the following:
Shallow connection boundary – the connection charge reflects the cost of
extension assets only. The cost of assets beyond extension assets are reflected
in ongoing usage charges.
The connection charge is paid on an annual basis. The new connectee is required
to provide user commitment for the period that the connection charge is
outstanding.
The ongoing usage charges include highly granular locational signals reflective of
local drivers of investment costs.
There is no user commitment requirement for wider network investment.
Advantages as expressed by Task Force members
Granular locational usage charges present a strong locational/temporal signal
(highly cost-reflective).
A shallow connection boundary is efficient for capacity allocation (i.e. no sunk cost
and users face cost-reflective usage charging instead). The remainder of the user
base is protected through securitisation without risk of cross-subsidy through
granular locational charges (i.e. reinforcements triggered within a given network
area would not be paid for by users elsewhere).
26
Good for smaller users, encourages connections, and provides cost certainty as a
small upfront cost and annnuitised connection charge provides a degree of cost
certainty.
Places an incentive on the network company to assess alternatives to traditional
reinforcements as capacity limits are reached, and to encourage flexible
responses.
Simple to administer, with no interaction required with the Capacity Market.
Disadvantages as expressed by Task Force members
The connection charge does not contain a locational element for any
reinforcement which may drive unnecessary costs or inefficient connections.
Lack of upfront charge or contribution to reinforcement through the connection
charge does not create commitment from the new connectee (i.e. may encourage
speculative applications).
Users may be unfairly treated based on their location or if energy usage is not their
core business which they have little control over and may unfairly penalise those
with infrequently high usage over peak times.
Highly granular charges may be complex, volatile and difficult to forecast
(location/time etc.) and respond to and so lead to inefficient user investment
decisions.
Difficultly developing a consistent approach and a level playing field between
transmission and distribution.
Nodal pricing may not be practical or feasible at lower voltage levels. Applying
nodal locational charging at LV or HV has significant issues that need to be
addressed, namely the practicality of implementation (as it would require network
companies to maintain powerflow models of their LV and HV networks) and the
potential for a postcode lottery (e.g. with rural users potentially facing a substantial
increase in their network charges).
This could have the effect of essentially shifting charges from developers to end
users (an example being a new housing development) and reducing incentives on
developers to accurately specify capacity requirements commensurate with future
needs. Ultimately it could lead to cheaper construction costs with higher energy
bills.
Summary – User Investment Decisions 4.12 A greater alignment of the principles, methodologies and arrangements for connection
and ongoing usage charging at transmission and distribution levels is desirable to avoid
boundary issues. This could be achieved by:
a common shallow connection charging boundary across all voltage levels in
transmission and distribution to encourage flexible responses from all connected
users (i.e. connection charges would just include extension assets with
reinforcement costs treated through ongoing usage charges); and
locational ongoing usage charges at transmission and distribution EHV only
generated by complimentary methods/models; and an HV/LV representative
model adjusted for locational issues e.g. a generation dominated network.
4.13 Studies indicate that use of user flexibility is likely to result in a lower cost network and
one that is more resilient to uncertainty. A shallow connection charging boundary, most
27
likely with the connection charge only covering extension assets at the time of
connection, will facilitate the use of flexibility by providing a direct price signal to compare
the cost of flexibility against network asset solutions. A shallow connection charging
policy on distribution networks would require more locational ongoing usage charges
further down the network. Applying a shallow connection charging policy further down
the network will therefore depend on how feasible it is to apply locational ongoing usage
charges at lower voltage levels whilst applying appropriate protection to more difficult to
serve communities.
4.14 Shallowish connection charges can create prohibitively high connection charges for new
users in constrained distribution areas leading to queues for connection. This may be
inefficient for the energy system. On the other hand, shallowish connection charges may
be appropriate in circumstances where it is not desirable to give strong locational signals
– for example, it may not be appropriate to give highly locational cost signals to smaller
(particularly residential) users as this risks creating a ‘postcode lottery’; if strong
locational signals are not in place for some users, a shallow connection charging
boundary would not be appropriate as the costs associated with the connection of a new
user would be inappropriately socialised. Some users may prefer the stability of charges
achieved through a deeper connection charging boundary than the potential volatility of
ongoing usage charges if the connection charging boundary were shallow.
4.15 Deep connection costs can act as a barrier to new investment and reduce the ability to
influence a user’s behaviour once they have connected – Ofgem moved away from a
deep connection policy in 2005 for distribution connected generation for this reason.
Moving to a deep connection boundary could act as a barrier to developing flexibility
services; given the electricity industry is likely to become increasingly reliant on flexibility
this barrier is likely to be undesirable.
4.16 C1-A (shallow connection charging with user commitment) or C1-D (shallow connection
charging with a strong focus on locational usage signals) would fit the above requirement
in terms of connection charging boundary. The difference between C1-A and C1-D is
the degree of granularity of ongoing usage charges. Whilst greater granularity can be
more cost-reflective it can also result in more volatile charges which are hard to predict
and hence less likely to influence behaviour. From a practical implementation point of
view, it may be preferable to limit locational signals to EHV connections, and hence a
shallowish connection charging policy may remain appropriate at HV and LV.
4.17 To reduce the risk of stranded asset costs, it is in the interests of all parties to ensure
that, where network capacity is increased in response to a user request, that increased
capacity is utilised. For this reason user commitment is a key requirement. In terms of
practical implementation, this could be restricted to larger connection capacities (e.g.
greater than 1MW). User commitment until at least the time of connection and potentially
for a period beyond connection would reduce the risk of stranded asset costs. These
requirements could be met by securitisation of a proportion of cost committed to provide
the capacity until connection (a feature of C1-A) whilst the beyond connection user
commitment could be met by a requirement to pay for any agreed capacity for at least a
fixed period of time (e.g. 5 years). Any introduction of post-connection user commitment
would need to be assessed against the cost of users obtaining the financial backing
required to provide such commitment, which may be disproportionate to the benefit
delivered.
28
4.18 There is a risk shallow connection charges reduce incentives on developers to
accurately specify capacity requirements commensurate with future needs, especially
where there is no ongoing relationship between the developer and the end users, e.g. a
new housing estate. For example, if a shallow connection charging boundary was in
place a developer could over-request network capacity (ensuring headroom for their
development) without incurring additional cost. If all of the requested capacity were not
subsequently developed, either ongoing usage charges would only be recovered in
respect of the actual connected capacity (leaving a shortfall to be recovered elsewhere)
or the locational ongoing usage charges of the connected users would be inflated to
recover the full cost of the requested reinforcement, neither of which impact the
developer. It may be possible to alleviate this risk by creating a dis-incentive for
developers to overstate capacity requirements by ensuring they retain a liability should
the capacity on a new development be underused.
4.19 For LV domestic and small business users, the introduction of core and non-core (i.e.
greater than core) access rights would ensure that additional requirements, which lead
to reinforcement, are recovered from the users who drive this cost. To avoid distortions
due to early or late adoption, costs for non-core use would be recovered via ongoing
usage charges reflective of the costs of reinforcement. By contrast, ongoing usage
charges for core use may be applied by user segment rather than geographic location
to avoid an arbitrary ‘postcode lottery’.
4.20 There are likely to be significant issues with transitioning to shallow connection charging
arrangements for all voltage levels. The requirement to incorporate grandfather rights
for existing users would need to be considered, potentially delaying the benefits of the
change and giving some users a disincentive to update connection arrangements, for
example, to release underutilised capacity. However access to local flexibility markets
and balancing/trading at a local level could be made dependent on existing users
accepting new arrangements.
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5. Assessment of C2 – Influences User Operations 5.1 This section summarises the views of Task Force members on the advantages and
disadvantages of five C2 cluster combinations when considered in the context of the
nine assessment criteria. The building blocks which define C2 are described in detail in
paragraph 2.20. The full views provided can be found in Appendix Five.
Four Cluster Combinations 5.2 Under cluster two, five cluster combinations have been considered as follows:
C2-A – temporal signals;
C2-B – extended Balancing Mechanism;
C2-C – full range of operational signals;
C2-D – bilateral trading; and
C2-E – market trading.
5.3 Each of these cluster combinations is considered in the subsequent sections.
C2-A – Temporal Signals
Description
5.4 This approach uses temporal (time of day) tariffs to influence user behaviour. Figure 8
represents the options selected under each building block to define cluster combination
C2-A.
Figure 8 - C2-A temporal signals
5.5 This cluster combination considers temporal (time of day) tariffs that can be used to
influence user behaviour. There are a range of possible implementations, ranging from
peak/off peak usage charges down to dynamic short-term prices that reflect costs on a
more granular basis (potentially down to individual Settlement Periods) and for individual
locations. These are not mutually exclusive, and it would be possible, for example, to
extend the use of red, amber and green timebands further down the network and also
introduce dynamic pricing for certain groups of users. The features considered under
this cluster combination include the following:
The introduction of ongoing usage charges which are more temporal in nature.
This is not restricted to consumption but could also include other elements such
as temporal capacity charges.
Introducing dynamic temporal signals (e.g. time signals which vary dynamically
every Settlement Period with minimal notice).
30
Introducing temporal charges that are set at a highly granular (e.g. nodal)
locational basis (e.g. each primary substation has a different set of temporal
signals – a primary substation might serve a small town or a large commercial
user).
There are no mechanisms for the reallocation of capacity rights.
Advantages as expressed by Task Force members
Dynamic pricing reduces the need for participation in complex mechanisms (such
as the Balancing Mechanism) and so avoids placing high costs on users.
Under temporal locational charging, users pay more when contributing towards
constraints, with common price signals regardless of whether a user is connected
to the transmission or distribution network improving price reflectivity of distribution
and transmission connected assets. This facilitates a more level playing field.
Dynamic and/or locational temporal price signals can provide a signal for users
who cannot, or choose not to, participate in the Balancing Mechanism.
Static time of use signals can be predictable and reflective if calculated ex ante
(i.e. in advance) and charged ex post (i.e. after the fact), allowing users to reliably
forecast their charges and modify their behaviour in response.
Time of use price signals may be effective for reflecting future network costs if
used as a proxy for user operational characteristics (such as reflecting the type of
profile of a particular demand user), rather than providing an explicit time of use
price signal to which a user is expected to respond.
Disadvantages as expressed by Task Force members
If time of use price signals fail to be fully cost-reflective, then they would provide
an unfair competitive advantage to users who are better able to take action to
avoid them, but for time of use price signals to be fully cost-reflective, they need
to be dynamic at high resolution (e.g. changing each Settlement Period). This
would make it very difficult for users to predict when planning their dispatch.
There is a risk of undesirable social outcomes if all demand is exposed to strong
temporal signals, for example if cost-reflective charges result in very high charges
at peak times, essential demand will be being penalised for unavoidable usage at
peak times.
Exposes the network company to the risk that users may over/under respond to
time of use price signals, so the network company may have to pre-emptively
reinforce its network to able to meet demand in a situation where users do not
respond. This is in contrast to options where the network company has greater
control over user specific responses and so can see the value users place on
access before deciding whether to reinforce.
There are potentially practical constraints and high costs in setting and applying
dynamic and/or locational prices for smaller users.
As there is no short-term reallocation of capacity in this option, the value users
place on access in constrained areas of the network must be revealed by the
ongoing usage charges in order to show where reinforcement is cost-effective.
Time of use prices may be an ineffective approach for reflecting future network
costs if network investment is driven more by a user’s capacity than by a user’s
particular operational behaviour in any given year.
There is a trade-off between operational time of use prices being effective which
users can respond to (static set in advance) compared with operational time of use
31
prices being cost-reflective (dynamic high granularity set in real-time). It may be
challenging to identify a useful balance between these two issues.
C2-B – Extended Balancing Mechanism
Description
5.6 This approach gives the network company a short-term mechanism to allocate real-time
access. Figure 9 represents the options selected under each building block to define
cluster combination C2-B.
Figure 9 - C2-B extended Balancing Mechanism
5.7 The features considered under this cluster combination include the following:
Dynamic management of constraints and optimisation of dispatch at both
transmission and distribution in real-time (i.e. efficiently operating the system by
considering the cost of constraint and allocating access).
There is no use of medium or long-term reallocation of capacity.
There is no use of temporal signals.
Advantages as expressed by Task Force members
Users who place a high value on access get to keep it, while users prepared to
give up their access are compensated and ’made whole’.
An extended Balancing Mechanism would be effective at providing spot price (i.e.
real-time) signals to those users who can respond to them, while avoiding
imposing operational risk and price signals on those users who can't.
The operational risk of operating the system falls on the network company, which
is best placed to manage it.
An extended Balancing Mechanism would give signals to both generation turn
down and demand turn up (assuming a generation driven constraint).
An extended Balancing Mechanism would take into account locational signals and
could optimise demand/generation around constraints.
Disadvantages as expressed by Task Force members
High engagement needed to participate, which could limit participation.
May need a 'de minimis' level at which this approach works, in which case there
is a risk of excluding some users from participation.
Risk of distortion if users with firm access are bidding alongside users with non-
firm access.
Relies on a cost-reflective investment signal being given through another charging
mechanism.
32
Would need to develop a methodology to stop gaming by exacerbating
constraints, as an extended Balancing Mechanism would likely provide a greater
benefit if constraints are exacerbated.
Relies on verification that action is taken as contracted – this is likely to be difficult
to implement for smaller users without smart systems.
C2-C – Full Range of Operational Signals
Description
5.8 This approach incorporates a number of the other features from within the C2 cluster to
develop a full range of operational price signals which could be used to drive user
behaviour, and has been included to enable a discussion on how different operational
signals could interact. Figure 10 represents the options selected under each building
block to define cluster combination C2-C.
Figure 10 - C2-C full range of operational signals
5.9 The features considered under this cluster combination include the following:
A short-term mechanism to dynamically manage congestion and optimise dispatch
in real-time at both transmission and distribution (i.e. efficiently operating the
system by considering the cost of constraint and allocating access).
Trading by users of well-defined medium-term and long-term access rights directly
with one another. Potential exchanges will require sufficient physical
interconnection and may not be possible in some circumstances due to network
constraints. To ensure physical compatibility, the network company would either
publish an exchange rate (i.e. how much 1MW of capacity in one area of the
network is worth in another area; 1MW in an unconstrained area is likely to be
worth less in an area that is more constrained) in advance or assess each trade.
Tariffs provide some temporal granularity (e.g. peak and off peak charges).
Tariffs are set in advance (e.g. at the start of each year) and provide some
locational granularity (i.e. charges that broadly reflect the regional drivers of
investment costs).
Signals could be applied to all users or could be applied to give different signals
to different users (e.g. constraint signals to larger users and tariff signals to smaller
users).
Interactions between Different Operational Signals
5.10 There are several possibilities for how the full range of operational signals could be used,
including:
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1. The full range of operational signals applied to all users for the use of a single
network. For example, all users could be exposed to time of use signals, an
extended Balancing Mechanism and bilateral or market trading opportunities for
access to the distribution network.
2. Different operational signals applied to different users for the use of a single
network. For example, an industrial user could be exposed to an extended
Balancing Mechanism for access to the distribution network, whilst a smaller user
was exposed to time of use price signals for access to the distribution network.
3. The full range of operations signals applied to all users for the use of different
networks. For example, all users could be exposed to time of use signals for
access to the distribution network whilst also being exposed to an extended
Balancing Mechanism for access to the transmission network.
4. Different operational signals applied to different users for the use of different
networks. For example, an industrial demand user could be exposed to an
extended Balancing Mechanism for access to both the transmission and
distribution networks, whilst a smaller user was exposed to time of use signals for
access to the transmission network and bilateral or market trading opportunities
for access to the distribution network.
5.11 Figure 11 shows a pictorial representation of each of these options, with a simplification
to only consider an extended Balancing Mechanism and time of use signals.
Figure 11 - Interactions between different operational signals
1. Full range of operational signals for all users:
o 1a – users exposed to both an extended Balancing Mechanism and time of
use signals for both the transmission and distribution networks.
o 1b – users exposed to both an extended Balancing Mechanism and time of
use signals for only the transmission network, while the distribution network
uses either an extended Balancing Mechanism or time of use signals.
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o 1c – users exposed to both an extended Balancing Mechanism and time of
use signals for only the distribution network, while the transmission network
uses either an extended Balancing Mechanism or time of use signals.
2. Different operational signals applied to different users:
o 2a – some users exposed to an extended Balancing Mechanism for both the
transmission and distribution networks, while other users are exposed to
time of use price signals for both the transmission and distribution networks.
3. Full range of operational signals for a user for different networks:
o 3a – users are exposed to an extended Balancing Mechanism for the
transmission network and time of use signals for the distribution network.
o 3b – users are exposed to time of use signals for the transmission network
and an extended Balancing Mechanism for the distribution network.
4. Different operational signals applied to different users for different networks:
o 4a – some users are only exposed to an extended Balancing Mechanism for
the transmission network, while other users are only exposed to time of use
signals for the distribution network.
o 4b – some users are only exposed to time of use signals for the transmission
network, while other users are only exposed to an extended Balancing
Mechanism for the distribution network.
Full Range of Operational Signals for all Users
5.12 It may not be economically efficient to provide operational signals from both time of use
signals and an extended Balancing Mechanism, and enable bilateral trading to the same
users for the operation of the same network. This is because, if any one of the elements
fails to be fully cost-reflective at any given time, this would result in market distortions,
conflicting incentives and arbitrage gaming opportunities to inefficiently avoid paying the
price signals which the network companies intended.
Different Operational Signals applied to Different Users
5.13 If the respective pros and cons of time of use signals, an extended Balancing
Mechanism, and bilateral trading were different for different types of user, then it may
be possible to use the entire range of operational signals but target each towards the
user that will respond to it most.
5.14 For example, if a type of user tends not to operationally respond to Balancing
Mechanism price signals (e.g. domestic core demand), then there may be a system
benefit in exposing that type of user to time of use operational price signals from network
tariffs instead. A key disadvantage of this approach is that it may result in different types
of user being exposed to different price signals, even though they may cause the same
cost or benefit to the network, which may result in a distortion to competition.
5.15 It may be practically challenging to prevent some users (e.g. behind the meter
generation assets) from being exposed to both types of operational price signals for the
same network. For example, behind the meter assets may respond to both demand time
of use operational signals, as well as choosing to participate in an extended Balancing
Mechanism as demand side response, and possibly via an aggregator. If there was a
35
desire to ensure behind the meter generators only faced one set of price signals (either
time of use or an extended Balancing Mechanism but not both), then it may be necessary
to exclude behind the meter assets from participating in the extended Balancing
Mechanism. A key disadvantage of this approach would be that it is likely to result in
less efficient balancing actions.
5.16 A similar approach could be taken with bilateral trading at a different time horizon to the
extended Balancing Mechanism (in line with existing arrangements at transmission
level), to mitigate conflicting price signals between trading and the extended Balancing
Mechanism.
Full Range of Operational Signals for a User for Different Networks
5.17 If the respective pros and cons of time of use price signals, an extended Balancing
Mechanism, and bilateral trading were different for different networks, then it may be
possible to use them differently, e.g. an extended Balancing Mechanism for the
operation of the transmission network and time of use price signals for the operation of
the distribution network.
5.18 For this to be economically efficient, it would be essential for time of use price signals to
be fully cost-reflective, otherwise the incentives for the operation of one network (e.g.
distribution time of use) may distort competition and the operation of another network
(e.g. transmission Balancing Mechanism) and distort competition in the wholesale
market.
Different Operational Signals Applied to Different Users for Different Networks
5.19 In this scenario, for example, generators connected to the distribution network may be
excluded from participating in an extended Balancing Mechanism for the operation of
the transmission network and instead distribution connected assets may only be
exposed to time of use price signals for the operation of the distribution network.
A key disadvantage of this approach would be that it is likely to result in significantly less
economic efficiency if distribution connected assets are excluded from competition to
provide services for the operation of the transmission network and could weaken existing
reform to widen access to the Balancing Mechanism through the Trans European
Replacement Reserves Exchange project (‘project TERRE’) and its associated code
modifications. Given the risk of creating advantage or disadvantage for some users,
differences in which signals users are exposed to would need to be well-justified.
Providing One Type of Operational Signal for All Users for All Networks
5.20 In this scenario, users would be exposed to only one type of price signal for operational
dispatch, which may involve providing only time of use price signals without any form of
extended Balancing Mechanism (i.e. cluster combination C2-A), or alternatively only an
extended Balancing Mechanism without any form of time of use signals (i.e. cluster
combination C2-B). Alternatively, the system could rely on only bilateral trading or
market trading (i.e. cluster combinations C2-D and C2-E respectively), with no
operational price signals from either time of use tariffs or an extended Balancing
Mechanism at all. This approach of using only one form of price signal could avoid
potential distortions which may arise from providing two or more different types of price
signal for the same purpose of incentivising users’ operational decisions.
36
Advantages as expressed by Task Force members
Location and time of usage impact investment, therefore sending these signals to
users is truly cost-reflective.
Weak locational and time of use signals may support access for all.
Potential for simple underlying time of use price signal for some users (e.g.
domestic) with an extended Balancing Mechanism on an opt-in basis.
Effective price signals across timescales encourage aggregation and competition
in supply, allowing economies of scale.
An extended Balancing Mechanism allows users to reflect their own costs to the
network company, which includes time of use and other network charges;
therefore better dispatch is achieved when users set their own costs.
Ability to hedge network access through medium-term products allows users to
manage the risk of the costs of network access and buy the access they require.
Incentive on users to flex usage and therefore collectively make better use of
existing capacity.
An extended Balancing Mechanism model provides price discovery (i.e. how
different users value access to the network) and clear economic evidence to
evaluate whether it is economically efficient to make particular network
reinforcement investments.
Disadvantages as expressed by Task Force members
Different approaches on different networks risk the approach on one network
distorting the other.
The network companies’ attempts to use an extended Balancing Mechanism tool
to manage operational dispatch may be hampered if users are also self-
dispatching for time of use price signals.
If some types of users are exposed to time of use tariffs, while different types of
user are exposed to an extended Balancing Mechanism, users which cause the
same cost or benefit may face different charges.
Difficult for this to work efficiently if different users have chosen different types of
access rights.
Volatile and complex signals limit the influence on user behaviour and so could
lead to excessive reinforcement.
Bilateral trading favours larger parties, reducing capacity trading overall.
Bilateral trading enables some users to arbitrage between other price signals
which may lead to economically inefficient behaviour in the extended Balancing
Mechanism and time of use responses via adverse selection (e.g. users using
bilateral trading to avoid paying the cost-reflective ongoing usage price signals
which the network company intended them to pay).
This would be very complex to optimise and there is a risk that the extended
Balancing Mechanism and time of use signals may not align.
This approach relies on high granularity of data - further work would be required
to understand any practical considerations arising from this.
C2-D – Bilateral Trading
Description
5.21 This approach has been developed to explore the benefits of developing a bilateral
traded market for access rights, and has been created to enable the benefits and
disadvantages to be explored. However, in reality, it could sit alongside some of the
other options. Under this approach, users would trade access rights directly between
37
one another (potentially with use of a centralised enabling system) with the network
company only involved to either assess the viability of each trade or to provide exchange
rates for specific trades. Figure 12 represents the options selected under each building
block to define cluster combination C2-D.
Figure 12 - C2-D bilateral trading
5.22 The features considered under this cluster combination include the following:
Access rights are initially allocated by the network company and then reallocated
on a short-term, medium-term or long-term basis with other users.
Direct trading by users with one another of well-defined access rights.
Potential exchanges will at the very least require the local connection assets to be
sufficient and may not be possible in some circumstances due to wider network
constraints. To ensure physical compatibility, the network company would either
publish an exchange rate in advance or assess each trade.
There are no locational or temporal tariffs with this option.
Advantages as expressed by Task Force members
Users trading bilaterally could potentially ensure efficient allocation of existing
capacity.
Requirements for capacity allocation on suppliers could encourage supply market
competition, lowering costs for users trading access.
The ability to aggregate demand and generation together could offset risk through
a portfolio approach, vertical integration and economies of scale.
Users will have sufficient view of their own costs once capacity has been secured
to make decisions about operation.
If combined with a deep connection boundary, risk may be reduced for users who
would otherwise be committed to paying deep connection charges.
Disadvantages as expressed by Task Force members
The network company would have poor control of the short-term operational
dispatch of particular users, which would make it difficult for the network company
to efficiently operate the system on an operational timeframe.
Bilateral trading favours larger parties, reducing capacity trading overall.
Bilaterally traded prices are more likely to be opaque, not publicly available and
very difficult to predict since they are based on a negotiated agreement based on
the value to the respective parties and their relative bargaining strengths.
There is a risk of economic distortions caused by using secondary trading to
arbitrage network charging arrangements which may result in users being able to
38
avoid paying the cost-reflective ongoing usage charges which the network
company intended them to pay.
Exchange rates are needed when trading access between different types of user.
It would be impractical for the network company to calculate these for different
types of users for different locations in real-time if there were a high volume of
bilateral trading.
Networks need a safeguard system, so that network companies have the power
to block trade transactions in case they may put the system at risk.
Trading in general cannot offer the user best value. By definition the access is
purchased/traded at ‘value’ and not cost (as it is now). As such the user will always
be paying over the odds.
Smaller users need to be allocated a capacity to be able to take part in the
mechanism.
Could disadvantage smaller users who give away access rights, which they need
at a later date.
C2-E – Market Trading
Description
5.23 Figure 13 represents the options selected under each building block to define cluster
combination C2-E.
Figure 13 - C2-E market trading
5.24 The features considered under this cluster combination include the following:
Access rights are reallocated on medium-term or long-term basis with other users.
Trading of well-defined access rights is via a market open to all users.
Potential exchanges will at the very least require the local connection assets to be
sufficient and may not be possible in some circumstances due to wider network
constraints. To ensure physical compatibility, the network company would either
publish an exchange rate in advance or assess each trade.
There is no short-term reallocation of rights or management of congestion.
There are no locational or temporal tariffs with this option.
5.25 A specific example of this approach would be to use trading to improve managing
capacity behind a constraint. Current constraint management arrangements at
distribution may require non-firm users to curtail their usage on a ‘last in, first off’ basis.
This may be sub-optimal and an approach could be adopted that incorporates market
dynamics. This might take the form of flexible users bidding to have the curtailment
requirement fulfilled by another user.
39
5.26 By comparison, the transmission network deals with this same issue using an auction
structure to trade curtailment via a central market known as the Balancing Mechanism.
Users provide bids and offers, which reflect the marginal cost of reducing or increasing
their generation. This results in a merit order (i.e. ordering of bids and offers by cheapest
to most expensive), which enables the system operator to select the most economically
efficient curtailment action from the entire market.
Advantages as expressed by Task Force members
Market trading would publicly display the value being revealed by users allowing
a wider audience to participate and therefore react.
The network company can add network conditions.
The absence of a requirement to participate in complex mechanisms such as an
extended Balancing Mechanism avoids placing proportionately higher costs on
users for whom energy is not their core business.
Requirements for capacity allocation on suppliers could encourage supply market
competition, lowering costs for users trading access.
Users will have sufficient view of their own costs once capacity has been secured
to make decisions about operation.
The ability to aggregate demand and generation together could offset risk through
a portfolio approach, vertical integration and economies of scale.
Disadvantages as expressed by Task Force members
The network company would have poor control of the short-term operational
dispatch of particular users, which would make it difficult for the network company
to efficiently operate the system on an operational timeframe.
A market could be complex to design and create a complex environment in which
to operate.
It would be difficult for users to anticipate what the market clearing price may be
when planning dispatch.
If secondary trading enables some users to arbitrage different charges at different
times, then net price signals received by users may be different from that which
the network company intended when the charges were originally calculated.
There could be a risk of speculative behaviour, putting some users at a competitive
disadvantage.
Trading in general cannot offer the user best value. By definition the access is
purchased/traded at ‘value’ and not cost (as it is now). As such the user will always
be paying over the odds.
Summary – Influencing User Operations 5.27 There are a number of ways in which it is possible to influence a user’s operation once
connected to the network. These options are not mutually exclusive, and it may be
possible to target different approaches for different types of users. Following discussions
within the Task Forces some clear messages have emerged in the area of user
operations.
5.28 Reallocation of access rights could offer benefits in certain scenarios. Providing users
with a wide range of access choice and the ability to vary this choice through the lifetime
of their connection will allow users to connect quickly (ahead of wider network
reinforcement) and to trigger efficient reinforcement at a time when user requirements
indicate this is appropriate.
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5.29 Within this, tools that allow fine tuning of real-time user operations can have an important
role to play in network charging, allowing control in a way which is not possible through
providing time of use price signals alone, particularly to resolve constraints, and ensuring
a more efficient use of the network for both demand and generation users. There are
many different ways in which this fine tuning could be achieved. One option may be to
extend to more voltage levels and users a structure similar to the current transmission
network’s Balancing Mechanism where users are compensated for their actions to
balance the system. Another option may be something closer to distribution active
network management arrangements where users are not currently compensated for
constraints. Furthermore, if there is a need to have grandfather rights as part of a
connection charging boundary change, trading of curtailment obligations could be a
useful option. The implementation of this solution could be costly to develop, administer
and participate in so consideration is needed as to whether the benefits make it
worthwhile. Typically, it is expected that this solution would be more viable for larger
users.
5.30 Reallocation of capacity through market-based or bilateral trading is likely to need to be
supported by network planning studies which ensure sufficient network capability and
exchange rates, particularly for trading across wide geographic areas. It may be practical
to set a capacity threshold for reallocation. Ensuring a level playing field between larger
and smaller users is likely to be important if bilateral trading is implemented. Whilst
auctions were not favoured by most Task Force members, they could be seen as a
potential way of valuing and/or trading constraint obligations (with the transfer value
between locations needing to be established by the network company).
5.31 Time of use charges can also have an important role to play in a solution for network
charging, reflecting that the costs of owning and operating a network vary across the
day and year and if applied consistently, supporting alignment between transmission
and distribution. These costs can be reflected in ongoing usage charges to incentivise
users to change their behaviour where it is economically efficient for them to do so.
Dependence on only user responses to time of use charges may not be sufficiently
resilient to prevent reinforcement to meet security of supply standards.
5.32 Locational charges can also have an important role to play. Widespread locational
network charging is easier to deliver at transmission and EHV because existing loadflow
models and network monitoring already approach high levels of granularity at these
voltages. Implementing a similar granularity of locational charging at HV and LV would
require improvements in the loadflow models and network monitoring used for these
voltages.
5.33 It is important to consider that different types of operational signal may be better suited
for different types of user or for different situations. It is also important to minimise
distortions which may arise if two or more different forms of price signal may provide
conflicting operational signals, or provide gaming opportunities; this could distort user
operations and lead to less efficient outcomes. However, how such different user types
are defined may be complex and care is needed to make sure distortions are not
created.
5.34 Reform of how user operations are influenced through charging must include
consideration of the feasibility and possible unintended consequences of the options
being considered.
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5.35 It is important that any solution put in place includes measures to avoid gaming. It must
also ensure a level playing field between small and larger participants – a risk particularly
noted with respect to bilateral trading. It requires users to have an agreed capacity and
under the current arrangements, this would restrict the solution to larger users.
5.36 If reform results in more complex arrangements, the interaction between the different
signals used needs to be considered carefully. Any distortions should be minimised
which may arise if two or more different forms of price signal provide conflicting
operational signals, or provide gaming opportunities; this could distort user operations
and lead to less efficient outcomes. There also needs to be a balance found between
reflecting the state of the network and its cost drivers and ensuring that users can
respond to the signal confidently and without excessive reliance on intermediaries.
5.37 If reform results in highly volatile signals, it will be important to consider any social
impacts of exposing core electricity needs (however defined) to such signals. It will also
be important to understand whether such signals can be managed effectively within
revenue recovery models.
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6. Assessment of Tariff Design and Charging
Methodology Options 6.1 This section summarises the views of Task Force members on the advantages and
disadvantages of tariff design and charging model options in the context of the nine
assessment criteria.
Tariff Design 6.2 The design of new network tariffs can draw on existing elements that are currently in
use at either transmission and/or distribution, or new elements could be created. The
elements that have been considered by the Task Forces are shown below and include
some new tariff elements which are not currently used. These are not mutually exclusive
and hybrid options may exist.
6.3 A combination of the following charging elements could be considered for forward
looking charges:
Fixed Charges (£/year) – charges which are applied on a per user basis as long
as the user remains connected.
Unit Rates (£/kWh) – standard unit charges, applicable to energy usage with a
number of sub-options for unit rates which vary by time of day and/or time of year:
o Unrestricted Unit Rates – a charge which applies to every unit used in all
time periods (e.g. currently used for the majority of non-half-hourly settled
domestic users at distribution).
o Static Time of Day Unit Rates – charges which vary by time of day with
time bands fixed throughout the year (e.g. the red, amber and green unit
rates for half-hourly site specific settled distribution connected users at LV
and HV).
o Seasonal Time of Day Unit Rates – charges which vary by time of day and
also time of year (e.g. the charges levied on pseudo-half-hourly Unmetered
Supplies users at distribution).
o Critical Peak Pricing (CPP) – charges which vary by time of day with a
narrow peak band in which the cost per unit is significantly higher (e.g. the
existing ‘super-red’ period for distribution connected users at EHV which
applies only to a relatively small number of time periods in the year, and at
the extreme half-hourly transmission triad charges which have a very narrow
‘critical peak’ period).
o Variable Time of Day Unit Rates – charges which vary (potentially up to
real-time) by time period depending on the level of demand at the time
(transmission triad charges have some features of this, in that the time
periods to which the £/kW unit rate will apply are variable based on the times
of peak demand, albeit the rates themselves are fixed at the start of each
year).
o Inclining Block Rates – under this option a lower unit rate would be applied
to usage below a certain threshold, and a higher unit rate to usage above
this threshold (note – more than two ‘blocks’ could be used).
Capacity Based Charges (£/agreed kVA, or £/kW) – charges levied in respect
of a user’s agreed capacity with the network company. Agreed capacities are
generally specified in bilateral Connection Agreements, and as such are only in
place for larger users at present. Four options have been considered:
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o Standard capacity charge – The capacity charge is applied to the capacity
agreed between the user and the network company. The rate is constant
across all time periods.
o Variable capacity charge – The capacity charge is applied as temporal
charge that can vary by time of day and/or time of year
o Excess Capacity Charges - (£/peak kW or £/peak kVA) – charges levied
alongside capacity charges where the user exceeds their agreed capacity.
o Notional capacity charges – Applying capacity charges to smaller users
who do not have an agreed capacity. Instead a representative notional
capacity is determined.
Reactive Power Charges (£/kVArh) – charges for usage of reactive power,
reflecting the difference between actual power (in kW) and apparent power (in
kVA), and where the two diverge due to poor power factor which drives the need
for increased network capacity.
Fixed Charges
Advantages as expressed by Task Force members
Simple to implement.
Fixed charges are completely predictable for the end user.
Charges are not affected by usage, so users shouldn’t be able to avoid them,
ensuring cost recovery over a wide base.
May be used to give a forward looking cost signal for costs which will be avoided
if the user disconnects.
May be appropriate for particular groups whose response would not improve if the
cost was more locationally cost-reflective, or if the fixed charge reflects a particular
element of cost which is the same for a given type of user or a given location.
Disadvantages as expressed by Task Force members
Does not incentivise the ‘right’ behaviour on its own.
Limited cost-reflectivity so will not create a level playing field on its own.
Risk of over-valuing 'off-grid' or behind the meter solutions if fixed charges are too
high.
Vulnerable users may be overcharged.
Question if these are predictable year-on-year.
Unit Rates
Advantages as expressed by Task Force members
Depends on the extent to which costs are driven per kWh and on the ability to limit
volatility.
A time bounded unit rate could signal the contribution to peak demand across a
diverse network and averaging over a period of time (such as the annual load
factor in transmission) would avoid conflicts between investment and dispatch
signals.
A unit rate is relatively easy for some users to avoid by taking action - to the extent
that these actions result in lower network costs, this is cost-reflective.
Potentially cost-reflective for some elements of the charge and hence better at
allocating risk.
At LV, energy usage reflects the cumulative contribution to any network
reinforcement requirements, protecting disproportionate allocation of costs to an
individual user.
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Disadvantages as expressed by Task Force members
If the unit rate is designed to incentivise investment decisions, then it may
incentivise inefficient dispatch behaviour.
Risk of over-valuing reduced usage if not targeted locationally or temporally.
Time bounded unit rates cannot be accurately applied to non-half-hourly metered
users as the network company has no visibility of the time of use.
Unrestricted Unit Rates
Advantages as expressed by Task Force members
Simple for users to understand.
Easily applied to all users.
Disadvantages as expressed by Task Force members
Limited cost-reflectivity so will not create a level playing field and not appropriate
for a forward looking charge.
Only action which can be taken is to reduce overall usage - moving usage to other
times has no impact on charges faced.
Lack of cost-reflectivity means inappropriate risk allocation.
Risks over-valuing lower overall usage and under-valuing reduced usage at peak.
Static Time of Day Unit Rates
Advantages as expressed by Task Force members
Depends upon the bands used, but is a versatile option to allow cost-reflective
forward looking charges and should create a level playing field.
Prices and time periods are known in advance, so users can respond to them.
May be useful to signal low cost network periods to demand users, such as
low/zero locational network charges overnight.
To the extent that usage of the network in fixed time periods drives network costs
and/or benefits, static time of use charges can be cost-reflective.
Disadvantages as expressed by Task Force members
May incentivise inefficient operational dispatch decisions relating to the differential
between the static peak band and the actual periods of constraint - this is because
periods of system stress are a function of outturn factors such as weather, demand
and market events, and so are inherently not static.
If network investment is driven by user capacity, then a price signal which aims to
affect user operational dispatch at times of peak demand may fail to be cost-
reflective of incremental future network investment.
If set globally, may encourage ‘wrong’ behaviours, e.g. increased generation in
generation dominated areas.
In this situation, the network company would be a price setter and volume taker
which may make it difficult to manage the operation of the network because they
cannot control how much capacity will respond to the price signal, or at what
location.
Static signals might be too crude to drive an appropriate response and it is doubtful
(especially at lower voltages) whether sufficiently sophisticated systems exist to
reflect actual constraints. In addition time bands would need to be sufficiently
granular to drive the correct level of response.
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Seasonal Time of Day Unit Rates
Advantages as expressed by Task Force members
Depends upon the bands used, but this is a versatile option to allow cost-reflective
forward looking charging and may create a level playing field.
Prices and time periods are known in advance, so users can respond to them.
May be useful to signal low cost network periods to demand users, such as
low/zero locational network charges overnight.
To the extent that usage of the network in fixed time periods drives network costs
and/or benefits, static time of use charges can be cost-reflective.
Easily applied to users with half-hourly metering.
Disadvantages as expressed by Task Force members
May incentivise inefficient operational dispatch decisions relating to the differential
between the static peak band and the actual periods of constraint. This is because
periods of system stress are a function of outturn factors such as weather, demand
and market events, which are inherently not static.
If network investment is driven by user capacity, then a price signal which aims to
affect user operational dispatch at times of peak demand may fail to be cost-
reflective of incremental future network investment.
If set globally, may encourage ‘wrong’ behaviours, e.g. increased generation in
generation dominated areas.
In this situation, the network company would be a price setter and volume taker
which may make it difficult to manage the operation of the network because they
cannot control how much capacity will respond to the price signal, or at what
location.
Cannot be applied to users with non-half-hourly metering.
Critical Peak Pricing
Advantages as expressed by Task Force members
Depends upon the bands used, but this is a versatile option to allow cost-reflective
forward looking charging and should create a level playing field.
Assuming the critical peak period and price are known in advance, users can
respond easily.
To the extent which network usage in the critical peak period drives network costs
and/or benefits, critical peak prices can be cost-reflective.
Disadvantages as expressed by Task Force members
May clash and distort response to other price signals which are also designed to
provide price signals which may be associated with periods of network stress.
Peak demand charging on its own would fail to provide an effective price signal for
generation dominated zones where network investment is required to mitigate
constraints caused by generation.
If network investment is driven by user capacity, then a price signal which aims to
affect user operational dispatch at times of peak demand may fail to be cost-
reflective of incremental future network investment.
In this situation, the network company would be a price setter and volume taker
which may make it difficult to manage the operation of the network because they
cannot control how much capacity will respond to the price signal, or at what
location.
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Variable Time of Day Charges Advantages as expressed by Task Force members
Potentially can be very cost-reflective and hence appropriate for a forward looking
charge.
Potential for very effective response for users with smart technology.
May tend to provide more cost-reflective operational dispatch price signals than
static time of use tariffs.
Disadvantages as expressed by Task Force members
Favours users with smart technology who can respond to short-term price signals
automatically. Therefore, it may be difficult for some (particularly small demand)
users to respond.
If network investment is driven by user capacity, then a price signal which aims to
affect user operational dispatch at times of peak demand may fail to be cost-
reflective of incremental future network investment.
In this situation, the network company would be a price setter and volume taker
which may make it difficult to manage the operation of the network because they
cannot control how much capacity will respond to the price signal, or at what
location.
May be challenging to calculate real-time dynamic tariffs and therefore likely to be
more difficult to implement.
May clash and distort response to other price signals which are also designed to
provide price signals which may be associated with periods of network stress.
As a method of providing an operational dispatch incentive, it may be
disproportionate and detrimental to expose all users to dynamic time of use tariffs,
even if many of those users cannot respond to them.
Inclining Block Rates Advantages as expressed by Task Force members
Meets service requirements of low usage users at low cost, whilst exposing higher
usage users (e.g. electric vehicle owners) to higher costs.
Easily applied to users with half-hourly metering.
Disadvantages as expressed by Task Force members
Smaller users may find it difficult to monitor when their usage is remaining within
the lower block in order to take action to avoid going over the threshold into the
higher block.
May clash and distort response to other price signals which are also designed to
provide price signals which may be associated with periods of network stress.
Not cost-reflective - an increment of usage does not impose fundamentally
different costs if driven by a high usage user than by a low usage user.
Dependent on the level of the rising blocks - risk of penalising large households
compared to smaller households for the same type of 'essential' usage.
Agreed Capacity Charges Advantages as expressed by Task Force members
Particularly well suited as an option for incentivising user investment decisions.
If incremental future network investment is driven by user capacity, then this could
provide an effective cost-reflective price signal.
Easily applied to larger users with bilateral Connection Agreements
47
Could be used with generators and load users grouped together.
It may be appropriate to reflect that different types of user (of the same agreed
capacity) may cause different incremental future costs to the network.
Users can obtain certainty by contracting in advance for the capacity (or 'access')
they require.
Disadvantages as expressed by Task Force members
Limited cost-reflectivity so will not create a level playing field and creates
inappropriate risk allocation.
Does not provide any operational dispatch price signal; therefore agreed capacity
charges would need to be combined with some other mechanism (e.g. an
extended Balancing Mechanism) to provide operational dispatch incentives.
Difficult to apply to smaller users who do not have bilateral Connection
Agreements (unless operating as a group).
Peak Demand Charges
Advantages as expressed by Task Force members
Can be cost-reflective if costs are driven by a user’s peak demands at certain
times; hence can provide a level playing field and appropriate risk allocation.
Requires sufficiently predictable windows of charge.
Encourages right amount of capacity to be bought.
Depends on the extent to which users can respond and the extent to which
appropriate flexibility can be purchased.
Disadvantages as expressed by Task Force members
Depends on the specific definition of peak, and so whether this results in stable or
predictable tariffs.
Likely to be difficult (particularly for small users) to respond to as requires a high
level of visibility of usage at all times in order to identify and reduce peak usage.
Network costs are driven by network peaks rather than individual user's peaks.
Network peaks are becoming increasingly unpredictable and so the ‘peak demand
charge’ timings in a day/week/season will increasingly be more varied, which could
result in unpredictable charges.
Reactive Power Charges
Advantages as expressed by Task Force members
Can be predictable for larger users with sophisticated understanding, and action
can be taken through upfront investment in power factor correction equipment.
Can be cost-reflective if proportional to the extent to which network costs and/or
benefits are driven by reactive power usage beyond the need for greater capacity.
Supports market for reactive power service providers.
Depends on the extent to which users can respond and the extent to which
appropriate flexibility can be purchased.
Disadvantages as expressed by Task Force members
Smaller users are unlikely to be aware of reactive power or be able to make
changes to respond.
A modification or exemption may be required for users which are providing a
reactive power service.
Impossible to apply for users without four quadrant metering.
48
Charging Methodology 6.4 There are three primary considerations for the charging methodology to be used – the
cost base of the charging model, the means by which locational charges are derived,
and the extent to which the methodologies used for the transmission and distribution
networks should align.
Cost Base
6.5 Three options have been considered for the cost base building block, namely:
transport model – cost of importing or exporting energy through an existing
network;
expansion model – levelised cost of future network based on a weighted average
of the existing network; and
remaining headroom model – cost of addressing the next constraint in
accordance with today’s design standards.
Transport Model
Advantages as expressed by Task Force members
Likely to result in stable and predictable prices.
Likely slightly more complex than existing LV and HV charging model but simpler
than existing EHV and transmission.
Disadvantages as expressed by Task Force members
Gives no indication of capacity and simply allocates costs of maintaining the status
quo.
Does not include cost based on absolute cost impact.
Lack of locational signals results in all user actions being given the same cost
signal regardless of the actual cost and/or benefit derived.
Lack of cost-reflective charges means that risk will not be appropriately allocated.
Requires locational and constraint costs to be reflected though other means e.g.
a deeper connection boundary.
Depends how granular/nodal this is worked out at. At a granular level, this can
become a disadvantage: backwards-looking tariffs reflect lumpy investment as
steep volatility, potentially driven by other user's new connections.
Price signal for flexible generators muted.
Gives no signal as to how a network develops and so no information to the network
company or user for better use of the network.
Expansion Model
Advantages as expressed by Task Force members
Signals areas of low and/or high capacity.
Symmetric treatment of demand and generation.
All users face the same symmetric cost-reflective price signal regarding both
increasing and reducing their access right to use the system, irrespective of when
they connected.
Avoids step changes in signals due to asset investment (saw-tooth effect), so
should be possible for an expansion model to result in reasonably stable prices.
Use of upfront assumptions (expansion constant and fixed asset costs) reduces
the need for the network company to make internal assumptions and so increases
transparency.
49
Avoids the highly complex requirement to attribute specific network investments
to specific network users.
Allocates risk, by avoiding exposing users to the consequences of decisions taken
by network companies which may result in over, or under reinforcement of the
network at particular times.
Proven track record of practicality since this approach is already used by the
existing transmission charging arrangements. More complex than the existing LV
and HV charging models, simpler than the existing EHV charging models, and
complexity as per status quo for transmission.
Disadvantages as expressed by Task Force members
Does not recognise specific reinforcement costs of addressing capacity
constraints.
If this model only provides relative locational signals (i.e. not absolute locational
cost signals) this could distort the market and impact competition.
Actual costs may be different from the average cost of reinforcement at any given
location - but this could be a somewhat localised signal by design.
This difference between actual costs and the signals provided means less cost-
reflective charges and therefore users do not face full incentives. The overall
network is likely to be less efficient as a result. Furthermore, risk may not be
appropriately allocated between users.
Symmetric treatment ignores engineering factors related to fault-level
reinforcement etc. This could be addressed by approaches such as using different
security factors for different types of user, or different tariff elements.
Signals may need to be strengthened by further locational and constraint cost
signals to be reflected though other means e.g. the transmission year round tariff
element, or a deeper connection boundary.
Can provide stable price signals but to the detriment of cost-reflectivity and hence
this will not be effective.
Remaining Headroom Model
Advantages as expressed by Task Force members
Signals areas of low and/or high remaining capacity and scale of increasing
capacity.
Increased recognition of reinforcement cost.
More closely linked to actual network and required costs/benefits due to users
actions and hence less distortion to competition.
Demand treatment highly reflective of security of supply standards.
Likely to provide better forward looking charges for demand users.
Site specific (but rule based) reinforcement costing.
Most cost-reflective approach means risk likely to be best allocated and likely to
lead to more efficient use of the network.
Highly cost-reflective by exposing users to the cost and/or benefit of network
reinforcements which their behaviour has the potential to drive and/or avoid.
Changes in security of supply standards are reflected in the treatment of demand.
Taking account of spare capacity on the network can lead to more efficient
locational decisions.
Status quo for EHV distribution charging and should be practical to use across all
voltages.
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Disadvantages as expressed by Task Force members
The predictability of the signal would be reduced, so users cannot effectively make
investment decisions which increases costs in short-term constraint management.
In the current distribution charging model, distribution connected generation would
not be subjected to a locational signal as there is no underlying security of supply
standard for generation on the distribution network.
Attributes specific network investments to specific network users which may over-
expose individual users to the risk that reinforcement is required.
If set nodally or zonally, then existing user's tariff can be affected by other users'
behaviour. Users may see this as a source of volatility and reduction in cost-
reflectivity, unless individual tariffs can be locked-in.
Penalising tariffs in constrained areas may discourage new providers of flexibility
(only contracted to relieve the worst excess, thereby taking the network to just full,
hence likely to incur a high tariff related to zero remaining headroom).
Significantly more complex than existing LV and HV charging models, and more
complex for transmission.
Relies on the network company to make subjective assumptions regarding what
future demands on the network may be in order to forecast what future headroom
may be and therefore what future network reinforcement may be required. These
forecasts will be subject to uncertainty, which can expose users to additional risk.
Relies on the network company to make a subjective judgement to attribute
particular network reinforcements to particular network users.
Locational Charging
6.6 Three options have been considered under the building block for generating locational
charges, namely:
a ‘500MW’ model (as used at LV and HV currently) or a probabilistic approach,
which assigns the costs of reinforcement to a user (or group of users) in proportion
to the probability that an increment of usage by that user will trigger reinforcement
on the assets to which that user is connected, i.e. a ‘cost allocation’ model;
DC load flow investment cost related pricing (DCLF ICRP), which calculates
optimal network flows based on expected peak demand being met by existing
generation, with charges calculated based on the impact of increments of capacity
at nodes on the network, i.e. an ‘incremental’ model; and
forward cost pricing which calculates the expected cost of reinforcement for a
given network group (i.e. a group of nodes), with charges calculated based on
recovering that cost over the calculated length of time until that reinforcement is
expected to be necessary, i.e. a ‘contingency’ model.
Probabilistic Approach
Advantages as expressed by Task Force members
Generalised model reflective of current engineering practice.
Likely to result in stable prices, therefore resulting in predictable price changes
which are likely to result in predictable user responses.
Recognises the cumulative effect of multiple users connecting to the network.
Relatively easy to implement - status quo at HV and LV, whilst simplification would
be required for use at EHV and transmission levels.
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Disadvantages as expressed by Task Force members
There would be no locational element to charges, so not specific to any site, i.e.
all user actions would be given the same cost signal regardless of the actual cost
and/or benefit derived.
Draws on propriety data/engineering approaches.
No or limited locational signal means charges are not cost-reflective and hence
likely to be distorted which does not create a level playing field (risk will not be
appropriately allocated). This also means that users do not face appropriate
incentives and hence the overall network is likely to be very inefficient.
Likely to require assumptions from the network companies when operating the
model which are subject to uncertainty and may vary between network companies.
Price signal for flexible generators muted.
DC Load Flow Investment Cost Related Pricing
Advantages as expressed by Task Force members
This uses an incremental load flow weighted average of the existing network as a
measure of expansion in order to calculate the long run marginal cost caused by
adding incremental capacity. The model would work by adding capacity (e.g.
1MW) of either generation or demand at particular nodes on the network, which is
then offset by a corresponding reduction of either generation or demand at either
a specific reference node or distributed across the network.
Signals areas of low and/or high capacity against an approximation of planning
standards.
Symmetric treatment of demand and generation – all users face the same
symmetric cost-reflective price signal regarding both increasing and reducing their
access right to use the system, irrespective of when they connected.
Use of upfront assumptions (expansion constant and fixed asset costs) reduces
the need for the network company to make internal assumptions and so increases
transparency.
Avoids attributing specific network investments to specific network users.
Some users consider this to be more cost-reflective than a transport model or
500MW model.
Avoids step changes in signals due to asset investment (saw-tooth effect), so
should be possible to result in reasonably stable and predictable charges based
on changes in use of the network, and so allows users to change behaviour.
Proven track record of practicality since this approach is already used by the
existing transmission charging arrangements. Status quo for (some) EHV
distribution charging and transmission.
Can reflect the different costs caused by different users by the way tariffs are
applied. For example, transmission has developed this methodology to include two
different charging backgrounds to reflect different drivers of investment (peak
security and year round), reflecting users’ operating characteristics associated
with the constraint costs by using a function for annual load factor, as well as
addressing implicit sharing by classifying generators into different types: carbon,
low carbon, conventional and intermittent.
Disadvantages as expressed by Task Force members
Use of DC Load Flow is a tool to simplify the study of a network - reflective for an
interconnected system but less reflective of physical power flows on certain types
of networks.
52
Too far removed from a dynamic operational model - flexibility providers
operationally supporting the network may be modelled here as causing issues in
the limited snapshot model, producing a disproportionally high tariff.
Only provides relative locational signals, not absolute cost signals, which is likely
to distort the market and impact competition.
Symmetric treatment ignores engineering factors related to fault-level
reinforcement etc. This could be addressed by approaches such as using different
security factors for different types of user, or different tariff elements.
If this model results in the lack of an absolute cost signal, this could result in
distortions and so may not create a level playing field (meaning that risk may not
be appropriately allocated).
Potential to result in volatile prices (particularly with the long run incremental cost
approach currently used for some EHV users), with a user's charges often
influenced by the actions of other users in the same location.
Relatively short-term predictability but still limited in the longer-term and is still not
fully cost-reflective.
Actual costs may be different from the calculated average cost of reinforcement at
any given location.
At a simple level, this could be unreflective of differing operational profiles.
Lack of cost-reflective charges means that users do not face appropriate
incentives and hence overall network likely to be very inefficient.
Significantly more complex than existing LV and HV charging models, and unlikely
to be possible to extend this approach to LV and maybe even HV charges.
Forward Cost Pricing
Advantages as expressed by Task Force members
Signals areas of low and/or high remaining capacity and scale of increasing
capacity.
Demand treatment highly reflective of security of supply standards.
Whilst likely to provide volatile signals, this does give the most cost-reflective
approach.
Site specific (but rule based) reinforcement costing.
Can be highly cost-reflective by exposing users to the cost and/or benefit of
network reinforcements which their behaviour has the potential to drive and/or
avoid, therefore risk is likely to be efficiently allocated, although a Task Force
member expressed a view that this approach is not necessarily more cost-
reflective than the other methods considered.
Status quo for (some) EHV distribution charging.
More closely linked to actual network and required costs/benefits due to users
actions and hence less distortion to competition.
Disadvantages as expressed by Task Force members
Allocates prices to network groups rather than nodes, so the approach can
optimise allocation between groups but not within a group.
Distribution connected generation would not be subjected to a locational signal as
there is no underlying security of supply standard for generation on the distribution
network.
A more cost-reflective signal for demand can be an advantage, but approach
needs to be adapted to provide similar for generation.
53
High volatility and low predictability in approach reduces the ability of network
users to respond to signals. This deteriorates further with a user's charges often
influenced by the actions of other users in the same location.
Volatility unwelcome to most users.
Significantly more complex than existing LV and HV charging models, and more
complex for transmission.
Relies on the network company to make subjective assumptions regarding what
future demands on the network may be in order to forecast what future headroom
may be and therefore what future network reinforcement may be required. These
forecasts will be subject to uncertainty, which can expose users to additional risk.
Relies on the network company to make a subjective judgement to attribute
particular network reinforcements to particular network users.
Fails to provide a symmetrical investment signal because it does not incentivise
existing users to reduce their use of the network.
This may require a relatively complicated and subjective methodology for dealing
with the issue that network investment is lumpy. Otherwise the entire cost of a new
network circuit could be allocated to an individual user, despite the new circuit
being built to serve many different existing, new and expected future users.
Alignment of Charging Methodologies
6.7 Three options have been considered under the alignment of methodologies across the
transmission and distribution networks building block, namely:
single model across all voltage levels;
transmission and distribution charging model different but with common
assumptions; and
different charging models across transmission and distribution.
Single Model across Transmission and Distribution
Advantages as expressed by Task Force members
Avoids distortionary investment incentives which may be simply be an artefact of
different charge calculation models.
Allows users to make comparable decision between transmission and distribution
investments.
Comparable costs give the ability to more efficiently allocate agreements to
generation, reducing cost to users and reducing the risk of stranded assets.
Disadvantages as expressed by Task Force members
May not reflect different planning standards or engineering practice etc.
In theory, this would provide a harmonised approach however it may lead to too
much complexity.
Requires significant work to achieve development of a common model which
appropriately reflects the attributes of all transmission and distribution networks
which have different planning and construction standards.
Transmission and Distribution Models Different but with Common Assumptions
Advantages as expressed by Task Force members
Aligned models are less likely to create distortions between networks.
More likely to allow appropriate comparison between connection and use of the
network at different voltages.
54
May be possible to agree common assumptions more easily than it would be
possible to achieve a common model.
Potential to deliver benefits of commonality without the need for full alignment of
charging assumptions which relate to different engineering standards.
Disadvantages as expressed by Task Force members
Some discontinuities will remain.
Different allocation of risk in Scotland compared to England, which is not justified
by the underlying engineering/physics.
Alignment of assumptions could be challenging given the different engineering
standards which apply.
Results in some distortion.
Different Charging Models across Transmission and Distribution
Advantages as expressed by Task Force members
Models can more closely reflect different planning standards or engineering
practice.
Avoids the need for complex work to align charging assumptions which relate to
different engineering standards.
Disadvantages as expressed by Task Force members
Potential for distortionary investment incentives which may be simply an artefact
of different charge calculation models.
Different allocation of risk in Scotland compared to England, which is not justified
by the underlying engineering/physics.
Modelling differences would require enduring fix and not just interim methods.
Current distortions are still present.
Summary – Tariff Design and Charging Methodology 6.8 The choice of tariff design and the specific economic model used to implement the
charging methodology needs to be appropriate to the choice of C1 and C2. The
advantages and disadvantages against the assessment criteria have been evaluated on
a standalone basis, but ultimately the advantages and disadvantages will be relative to
the choices of C1 and C2 and other areas. Nonetheless, the discussions within the Task
Forces have resulted in some key messages in the area of tariff design and modelling.
6.9 Cost-reflective time of use tariffs create incentives for users to amend their behaviour to
benefit the network. At present distribution network charges only vary by time of use for
a portion of users (primarily larger users, although some smaller users are exposed to
two rate tariffs). Extending time of use tariffs to all users would be beneficial as it extends
the price signal to all users and drives innovation as smaller users become incentivised
to reduce their costs. In order for any benefit to be derived from network time of use
tariffs, it is necessary for these to be passed through to end users. Seasonal tariffs offer
a more targeted price signal. At present the only seasonal network charges are at
transmission (for half-hourly settled users) and Unmetered Supplies that are settled on
a pseudo-half-hourly basis. Moving to a seasonal price would allow network companies
to set more cost-reflective charges for users. The visibility of appropriate data to allow
users to forecast future charges is seen as vital to any of the proposed solutions.
6.10 Capacity charges do not currently provide a universal incentive for users to profile their
capacity. Distribution capacity charges are currently a flat rate based on the agreed
55
capacity of the user. Under the current arrangements the transmission Balancing
Mechanism complements the network capacity charges by providing an incentive for
users to relinquish operational use of the network at times when there may be insufficient
network capacity. The current development of active network management schemes
could perform a similar operational role for the distribution network; however this could
conflict with the application of time of use tariffs.
6.11 Inclining block rates could potentially penalise users with high consumption but flat
profiles. The rationale for inclining block rates is to use increased consumption as a
proxy for capacity. However, in some cases (such as economy 7 or 10 users) high
consumption is primarily during the off-peak period and therefore the additional
consumption should not incur the higher rate. The design of future tariffs might need to
reflect the use of core and non-core capacity; however this is also true of a number of
other elements which could be taken forward as part of any change to network access
arrangements.
6.12 A natural split exists between LV/HV networks (where the bulk of users connect) and
EHV/transmission. Although three charging methodologies exist at EHV and
transmission, they are trying to achieve the same aim of cost-reflective locational prices.
There is merit in trying to rationalise and increase commonality to avoid distorting
demand and generation users’ decisions to connect at distribution EHV or transmission
respectively (i.e. avoiding perverse incentives), and to ensure that users are exposed to
the costs they impose on the whole system and just the network to which they are
connected. However, locational charging at HV and LV is not yet possible or practical
and could have unintended consequences for some users. It will need to be determined,
if changes are felt to be appropriate, whether this should be a single model covering all
voltages or two models which reflect the different arrangements.
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7. Access Properties 7.1 This section further defines and considers the key building blocks which, when
considered together, would define the terms on which a user accesses the electricity
network. It then summarises feedback received from various stakeholder groups from
within the Task Forces, before considering whether different access arrangements will
be necessary for domestic and micro business users (including vulnerable users).
Access Building Blocks 7.2 The Ofgem working paper identified the key building blocks of access as:
time aspects;
firmness;
geographic nature; and
associated conditions.
7.3 The Task Forces’ initial options report redefined access rights in terms of:
Depth: The concept where users only require access to certain voltage tiers and
that these voltage tiers can be used as building blocks to define their access. In
practical terms this is related to the physical firmness of access and the degree to
which access is shared between users on different parts of the network;
Lifespan: The timeframe and lifespan of the required access is likely to drive
different connection solutions and may bring about different costs on the network;
Time of Use: Access could vary according to time of use, ranging from time of
use within a day to seasonal periods throughout the year;
Firmness (financial and physical): Whether a user’s access is firm or non-firm
is used in the context of both demand and generation to describe either: the level
of physical resilience (known as physical-firmness i.e. more than one spare
circuit); or financial protections (i.e. compensation for times when access is not
available); and
Standardisation of access: Access options could be defined in standardised
terms to reflect the network complexity and number and type of users. Different
options which reflect the specific characteristics of specific users could be offered
alongside ‘off the shelf’ solutions, with options applied to all users on a universal
basis, a segmented basis, or an opt-in basis.
7.4 Views were sought from network users on their preferred options for these access
characteristics, which are described further below.
Users’ and Access Providers’ Perspectives
7.5 The Task Forces considered how they thought different users would value choices in
access rights at point of connection, and gathered feedback from Task Force members
characterised according to a set of stakeholder groups, namely:
large, transmission connected generation users;
distribution connected generation and storage users;
community energy users;
57
large demand users; and
domestic users.
7.6 For completeness the Task Forces also gathered feedback from potential access
providers, in this context:
the Electricity System Operator; and
Distribution Network Operators.
7.7 The views expressed by Task Force members on network users’ and access providers’
perspectives are collated in Appendix Eight, and are summarised below. Regardless of
the options selected under each of the access properties, there will be a need to ensure
that the charges associated with each combination are cost-reflective.
Depth
7.8 All types of network users expressed a preference for full network access (i.e. across
transmission and distribution networks) for participation in national energy markets.
Distributed generation, community energy users, large demand and domestic users
expressed a preference to have the option of only being part of a local energy market
instead, if opportunities existed, although concerns were raised about market splitting
and how local arrangements would work in practice, especially the contribution to or
avoidance of wider networks costs.
Lifespan
7.9 Most large demand and generation network users preferred a wide range of lifespan
choices from short term (i.e. by month) to long term (i.e. 40 years plus), whereas others,
including domestic users preferred evergreen rights.
Time of Use
7.10 Again most large demand and generation network users preferred a wide range of time
of use choices for contracted access rights from varying capacity at different times (i.e.
within day, month or year) to long term (i.e. 40 years plus), while others preferred less
optionality with access rights for all users flat annually. There may be an opportunity for
domestic users to respond to varying time of use, but access safeguards must be in
place for some domestic users to have static or fixed access.
Firmness (Financial and Physical)
7.11 There was a range of views regarding whether all users should be financially firm,
financially non-firm, or have the choice. All network users expressed a preference to be
connected to a highly reliable electrical network (e.g. >99.99% reliability), with
generators and storage stating that unavailability should result in financial
compensation. It was noted that the introduction of financially firm arrangements at the
distribution network level would be a significant change likely requiring careful definition,
amendment to security standards and more importantly acceptance from other network
users that they would fund any unavailability payments.
Standardisation of Access
7.12 There was a mixed response across network users on the level of standardisation versus
bespoke access arrangements with a leaning towards standardisation. Large
transmission connected generation stated a preference for the same rights for all, with
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community energy users preferring access choices that enable local supply to match
demand and domestic users preferring simple to understand arrangements.
Safeguarding for Domestic Users (Including Vulnerable Users) and
Micro-businesses 7.13 Domestic users and micro-businesses (including vulnerable users) require network
access to meet their essential needs. This core level of access is presently supplied on
a non-firm basis, only interrupted for the minimum duration should a fault occur. Most
small users will not be aware of and potentially not interested in flexible arrangements
where they could be interrupted more frequently to manage network congestion.
7.14 Work under the Energy Network Association’s Open Networks project has identified
different levels of future engagement with flexibility9. Passive customers (such as many
domestic, micro businesses and vulnerable users) may not be able to, or may choose
not to, actively engage in flexible arrangements. This should not become an obstacle
to equitable access for their essential needs. Vulnerable users may find it particularly
difficult to navigate more complex access arrangements and could face the risk of
making the wrong choices in securing low cost access. However, the potential growth
of flexibility services is dependent on some electricity users having the option to adopt
a more flexible arrangement.
7.15 Amendments to the access rights of users will need to protect smaller users from
inadvertently relinquishing core access rights, which they may later regret. Likewise,
protections will be needed to ensure new users (due to a house move, new connection
or similar) have the same core access rights and protections to also meet their essential
needs.
7.16 As domestic energy choices change, access requirements may extend beyond a core
level for essential needs and may trigger reinforcement of the wider network. The Task
Forces have not defined what is considered core or non-core access, but differentiation
between the two could allow the development of specific arrangements for users who
require more than the core. Arrangements for non-core access could allow the forward
looking costs of related wider reinforcement to be clearly signalled, enabling users to
make informed choices (such as choosing an interruptible electric vehicle charging
arrangement or responding to time of use tariffs).
7.17 Whilst auctions and other forms of market trading could allow larger commercial users
to secure access based on their ability and willingness to pay, such arrangements could
directly conflict with the need to ensure equitable access for a household’s essential
needs. Even with aggregation of smaller users into larger pools, perhaps via suppliers
or new actors, there is concern that virtually identical users would end up with different
outcomes depending on the ‘buying power’ and risk tolerance of a particular pool.
7.18 This thinking points to a benefit in defining simple core access arrangements for
vulnerable users and for those domestic and micro-business who only want access
under similar arrangements as they enjoy now. This should not preclude other options
for those users who want to engage more with future flexible arrangements.
9http://www.energynetworks.org/assets/files/electricity/futures/Open_Networks/Customer%20Category%20descriptions%20190613.pdf
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8. Initial Allocation of Access 8.1 This section further defines and assesses methods of initial allocation of access rights,
before going into further detail on auctions, defining various permutations of auctioning
access rights, supplemented with expressed opinions from Task Force members.
Initial Allocation 8.2 Three options have been considered for the initial allocation of access rights, two of
which are developments of a ‘first come, first served’ approach:
First come first served:
o First come first served with additional queue management.
o First come first served with Connect and manage.
Auctions/trading.
First Come First Served
8.3 Under this method of allocating access rights, a user who contracts for an access right
will be allocated that access right in accordance with their application. They, implicitly,
retain that access right until such time as it is surrendered by them i.e. their access is
evergreen. The arrangements in distribution are perceived to be economically inefficient
and unfair for some user types (for example larger distribution connected generation);
however new users will continue to seek certainty of required capacity being available
at the point of their investment decisions. This approach provides a challenge for queue
management for users waiting to connect, in that there is nothing to prevent a first
connectee inefficiently blocking later projects.
First Come First Served with Queue Management
8.4 Under this method, additional queue management steps are taken to prevent inefficient
blocking. There are many potential options for dealing with first come first served queue
management, including use of development milestones whereby the prospective
connectee must commit to progression milestones to demonstrate how they will achieve
their connection date. If the prospective connectee does not meet the progression
milestones or is not ready to connect in line with the milestones, they will lose their initial
queue position and another prospective connectee further down the queue (i.e. a
prospective connectee who has accepted their connection offer at a later date) can
progress. Alternatively, queue management may be carried out by providing a price
signal based on user commitment for the cost of network reinforcement, or enabling
users to trade their position in the queue on a bilateral basis. This would ensure capacity
made available by reinforcement is utilised at the earliest opportunity.
First Come First Served with Connect and Manage
8.5 This mechanism allows users (presently only generators under transmission
arrangements) to connect where physically possible once extension assets are
complete without the need for wider reinforcements to be initiated immediately.
However, this only provides physically non-firm access, with financially firm access
being secured through a separate process. This has the advantage of speeding up
access to the market when compared to the basic first come, first served mechanism.
However, the connect and manage approach has the potential to increase associated
constraint costs behind some boundaries e.g. through constraint payments. At
transmission, the user retains financially firm access and is paid when constrained off
the system. At distribution, users connected to flexible connections do not have firm
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access under a connect and manage type agreement and accept the possibility of some
curtailment when a constraint occurs, without constraint payments.
Auctions and Trading for Initial Allocation
Universal Auctions
8.6 The use of universal auctions for the allocation of access rights has raised some
concerns amongst Task Force members. Advantages and disadvantages are
summarised in the earlier section on the ‘high emphasis on auctions/trading’ framework
scenario (following paragraph 3.2), with a common theme being that there is a need to
safeguard smaller users from the complexities of auction participation, and the risk of
undesirable social and economic consequences associated with being unsuccessful in
an auction and so losing network access. This report provides more on the potential
effects on vulnerable users in paragraphs 7.13 to 7.18.
Targeted Auctions
8.7 An alternative to a universal use of auctions to allocate access is to use targeted
auctions under certain situations or scenarios where they may provide a more focused
benefit. Below are two potential scenarios (initial allocation of existing or new
unallocated capacity and identifying ‘spare’ capacity to support initial allocation) where
targeted auctions may offer benefit and an illustrative example for how they could be
applied. However, it should be noted that even targeted auctions had limited support
among Task Force members, including because of complexity and potential volatility in
outcomes.
8.8 There may be issues in seeking valuation prices for capacity across different auction
windows given that investment to create capacity is lumpy by nature. Consideration is
required on the potential merits of using a reserve price, possibly based on long-run
marginal costs for incremental capacity. If the reserve price was not met, the investment
in new capacity would not take place and constraints would continue to be managed
operationally. Combining targeted auctions with managed secondary trading might
reveal more consistent prices. However, in a commercial auction there may need to be
mitigation measures if trading created the risk of over-inflating the value of capacity.
Initial Allocation of Existing or New Unallocated Capacity
8.9 Auctions could be used to allocate any existing unallocated capacity and also any new
capacity being released onto the network from new investment or changes in network
use. An example of how this could be done is described below:
Volume of capacity available determined 12 months ahead (i.e. existing network
capacity and any planned reinforcement).
Auction assigns firm access to successful bidders but all users get access (i.e.
unsuccessful bidders are assigned non-firm access).
Revenue generated from the auction could be used to invest in the network,
allowing some users with non-firm access to subsequently convert to firm access.
8.10 The use of auctions in this scenario would have the largest influence on how users make
decisions at the time of investment with little impact on use of the network once
connected.
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8.11 Holding auctions for large numbers of users presents significant timing and process
issues. ‘Gating’ the auction process (i.e. holding an auction on a specific date) may have
implications, including for the consenting processes of participating parties.
Identifying ‘Spare’ Capacity to Support Initial Allocation
8.12 It may be possible to establish mechanisms to identify ‘spare’ or unused capacity
allocated to existing users that could be ‘recycled’ to improve the efficiency of initial
allocation. However, establishing a definition of spare capacity needs careful
consideration.
8.13 It is potentially inappropriate for a user to have evergreen rights to unused capacity,
especially without ongoing cost signals. Users could be incentivised through cost-
reflective charges to use or release unused capacity. Consistent arrangements for
demand and generation users’ capacity retention may be achieved by appropriate
application of stronger capacity charges.
8.14 The new arrangements could either be mechanistic based on, for example, the
generation users capacity that is subject to a contract (such as under the Capacity
Market or Contract for Difference); unused capacity identified through ‘use it or lose it’
arrangements; or demand or generation users willing to change usage behaviour. This
capacity could then be made available to all users through an auction-style process.
8.15 This arrangement is likely to affect both users’ investment decisions and also their usage
behaviour where a connection to the network already exists.
8.16 It is important to note that network companies already take account of implicit sharing
via the diversity of users, including LV diversity, such that apparent spare or unused
capacity may already be being used by other existing users. For example, the spare
capacity for the times when a gas peaker is not running may have already been implicitly
allocated to existing renewable generators, so is not in fact unused, spare, or blocking
other new users.
8.17 The concept of reallocating spare capacity will be more relevant when considering a
scenario with deep connection charges and weaker ongoing usage signals e.g. where
there is no avoidable ongoing usage price signal to incentivise users to give up surplus
connection capacity.
Task Force Members’ Views
Advantages of Targeted Auctions/Market-Based Approaches as Expressed by Task Force
Members
Access is allocated based on users’ perceived value and ability to pay rather than
first come first served which may increase the range of financially viable projects.
These mechanisms can reveal the value of access to users, and so provide a
signal to network companies where investment might be prioritised based on
where genuine demand is high at that point in time.
Disadvantages of Targeted Auctions/Market-Based Approaches as Expressed by Task
Force Members
Charges based on the outcome of auctions will be value-reflective rather than cost-
reflective which would be a disadvantage as cost-reflectivity is a desirable feature
of future arrangements.
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Auctions will naturally favour those with the most funds, but will not necessarily
release network capacity since auction winners could continue pay to maintain a
holding position without necessarily progressing construction.
Likely to exclude non-expert participants such as communities.
The different business models of businesses participating may put them at an
advantage or disadvantage.
Auctions would be complex to implement, with a potentially high administration
burden on participants.
High uncertainty of allocation of access.
Participants will find it difficult to align the timescales of their grid connection and
planning permission under a ‘gating’ process (i.e. holding an auction on a specific
date).
Depending on the auction method chosen, this may unfairly benefit those users
who may find themselves at the front of the queue since they would be able to sell
an asset (queue position), which they themselves had not paid for. This could
result in unintended consequences such as a rush to join the queue as early as
possible on a speculative basis.
Auctions may still need to co-exist with queuing systems or pre-qualification for an
auction as users will bring forward connection applications at different times. The
queue will need to be reconciled against holding an auction to ensure fairness
between participants.
There could be severe impacts on local economies of a large user losing access
in an auction.
Auctions are not seen to work with secure transmission networks built to GB
Security and Quality of Supply Standards (GB SQSS).
Summary 8.18 Task Force members considered two options for initial allocation of access rights,
namely auctions and first come first serve, as well as the consequential impacts of their
implementation.
8.19 Following on from these two options, different permutations of auctions have also been
assessed at high level, including the use of targeted auctions or universal auctions. In
addition to this, two variations of a first come first served methodology have also been
evaluated by Task Force members. Summaries have been provided of each of the
options along with the pros and cons. Whilst there has been a range of views between
Task Force members, the following key messages were consistent across the Task
Force:
There will always be an element of first come first served whether it relates to the
connections process or in relation to the readiness of a user’s project to participate
in an initial allocation process. Auctions with gate closure may be difficult to align
with the timescales of multiple users’ construction projects.
There are significant levels of risk associated with implementing universal auctions
for access rights. There is pure economic merit in access being subject to a
commercial auction because access would be secured by those who value it most
and are more likely to utilise it fully; however there may be wider socio-economic
consequences where some users are securing better access than others. The
risks extend beyond the energy industry and could have detrimental impact across
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the wider economy as well as on vulnerable and smaller users. This impact as not
been analysed or evaluated in full.
There is value in considering the potential for auctions on a targeted basis,
allowing the procurement of access rights on a competitive basis. However, such
an approach would need to be taken with careful deliberation on how it would
impact current and future network users as well as how it would integrate into the
existing regulatory framework. This would likely have a greater effect on
investment decisions as opposed to operational dispatch decisions. It should be
noted that any form of auction would present significant operational, economic and
political challenges that would require full and comprehensive evaluation.
The reallocation of ‘spare’ capacity may present the opportunity to make more
efficient use of existing levels of capacity for initial allocation. The mechanics of
this approach would require consideration to how the term ‘spare’ is defined e.g.
it may be voluntarily surrendered if unused or require a mechanistic approach
based on a user’s contracted terms. This arrangement is likely to be more relevant
when considering a scenario with deep connection charges and weaker ongoing
usage signals.
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9. Plausible Packages 9.1 This section aims to highlight the links between different clusters combinations and
building blocks, and provide examples of how these might be linked together.
Overview 9.2 Figure 14 provides a condensed overview of all of the cluster combinations and building
blocks that have been discussed in the previous sections. Certain options may be
combined into ‘plausible packages’ that could be taken forward as potential new
arrangements for network charging and access. This section attempts to describe the
sum of those packages.
Figure 14 - Tree diagram showing how options combine
9.3 It should be noted that in order to implement certain packages there are dependencies
between the options described, including that:
changes to the access regime will require a charging methodology that reflects the
new arrangements;
a new charging arrangement may be conditional on the definition of access rights;
the implementation of auctions is conditional on the definition of access rights;
certain options to influence user investment would require charging models that
are able to provide strong locational signals; and
certain options to influence user operations would require the network companies
to actively manage their networks and send appropriate operational signals either
through dynamic charging or other mechanisms.
Illustrative Examples 9.4 The following packages have been developed from the work described in the previous
sections. They are not intended to be fully worked up examples; rather they are
representative of different ways in which network access and charging arrangements
might be developed. The packages have been selected by Task Force members on the
basis of their observations of the different combinations that are available in the two
clusters. They are provided therefore as a starting point for discussion about future
approaches. Whilst all four of these packages use a shallow connection charging
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boundary, this does not preclude similar packages which could incorporate a shallowish
connection charging boundary, with the effect of increasing the connection charge signal
and correspondingly reducing ongoing usage signals. The four packages are as follows:
Package one – emphasis on ongoing usage charges with limited user choices.
Package two – emphasis on ongoing usage charges with high user choice.
Package three – emphasis on bilateral trading and an extended Balancing
Mechanism.
Package four – emphasis on time of use signals with no contracted access.
Package One: Emphasis on Ongoing Usage Charges with Limited User Choices
(including cluster combinations C1-A and C2-B)
9.5 This scenario is designed to deliver a clearly defined access product to make it easier
for network companies to price cost-reflectively. Ongoing usage charges are calculated
as a function of specific user characteristics to reflect how different types of users cause
different types of network cost (e.g. transmission uses different classifications:
conventional, intermittent, carbon and low carbon), and reflects the impact of different
users on the cost of constraints by a measure of their annual load factor.
9.6 Shallow connection charges mean that users are free to respond to those price signals
by increasing or reducing their contracted capacity, which reduces the need for
secondary trading.
9.7 This package is relatively close to the existing transmission arrangements, so is a
relatively low change option and effectively involves bringing distribution in line with
transmission.
9.8 Figure 15 gives a representation of package one.
Figure 15 - Emphasis on ongoing usage charges with limited user choices
9.9 The features of this package are described below:
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Initial allocation – initial allocation would be on the basis of access right choices
on a connect and manage basis. At any time, users could apply to the network
company to ask for an initial allocation of access.
Locational investment signals – the network company would use a charging
model to calculate cost-reflective locational ongoing usage charges, which users
would be liable to pay on an ongoing basis as long as they continue to have access
to the network.
Access depth – all users would have access to the National Balancing Point and
there would be no choice for users to restrict their access to local access only.
Duration of access – access lifespan would be evergreen, so users would not
have the option of choosing between time limited access products of different
specific durations.
Granularity of access – access resolution would be annual, so users would not
have the option of choosing between specific access periods such as by season,
by Settlement Period, or any other specific time period.
User commitment for connection – under this package a new connectee
seeking connection to the GB electricity network would be required to provide user
commitment security for shallow connection charges. These connection charges
would relate to specific assets required to connect the user to the wider electricity
network. The new connectee would retain the liability to pay for the connection
over the lifetime of the relevant assets.
User commitment for wider reinforcement – the new connectee would provide
security for wider network reinforcements that are required as a result of the new
connection. The liability for these wider network securities would fall away once
the new connectee was connected to the network (i.e. once the connection was
energised and operational).
Firm access – all users would have firm access. Firm capacity rights would be
both financially firm and physically firm. Firm financial rights would be associated
with a level of compensation for the firm rights if the network were unavailable via
an extended Balancing Mechanism.
Non-firm access – users would not have the option of choosing non-firm access,
either physical or financial.
Changing access rights medium-term to long-term – users would be able to
apply directly to the network company to request to change their contracted
access. There may be specific minimum notice periods, such that users would
only be able to reduce their access in a way which enables them to avoid paying
ongoing charges at a minimum of e.g. 12 months’ notice before the year for which
the access applies.
Changing access rights short-term – there may be an arrangement under which
users could apply to the network company for some form of special short-term
access product for users who wish to change their contracted access within year.
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This product would be at less attractive prices compared with contracting for
access in advance in order to encourage users to contract in advance.
System operation – operational signals would be provided by an extended
Balancing Mechanism. All users would be entitled to participate in the extended
Balancing Mechanism, either directly or via an aggregator. Participation would
only be compulsory for larger users and on an opt-in basis for smaller users.
Generators would post physical notifications of the capacity they expect to
generate along with bid and offer prices for reducing or increasing that generation,
with a similar approach used for demand and demand side response.
9.10 Under this package, new arrangements would be needed for connection at the
distribution level, with alignment between connection arrangements at transmission and
distribution. This approach is very similar to existing arrangements for transmission;
however, it would likely require a new charging model approach for distribution. It would
also benefit from a consistent definition of nodal capacity across both transmission and
distribution to derive locational marginal signals across zones. The charging model
would need to reflect the dual drivers of network investment cost, firstly to ensure
security of serving demand and secondly to ensure the economic transport of power.
There would need to be consideration regarding how an extended Balancing Mechanism
approach could best be implemented for smaller users.
Package Two: Emphasis on Ongoing Usage Charges with High User Choice
(including cluster combinations C1-A and C2-B)
9.11 This package is similar to package one, except with more optionality for users.
9.12 This package delivers a high range of choice for users, which may make it more difficult
for network companies to provide a cost-reflective price for every permutation of options.
The high degree of optionality means that users do not need to trade their access rights,
because they are able to choose whatever combination of access rights they would like.
9.13 Figure 16 gives a representation of package two.
Figure 16 - Emphasis on ongoing usage charges with high user choice
9.14 The features of this package are described below:
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Initial allocation – initial allocation would be on the basis of access right choices
on a connect and manage basis. At any time, users could apply to the network
company to ask for an initial allocation of access.
Locational investment signals – the network company would use a charging
model to calculate a cost-reflective locational ongoing usage charge, which users
would be liable to pay on an ongoing basis as long as they continue to have access
to the network. The network company would need to calculate different prices to
reflect the many different combinations of access options which users would be
able to choose between.
Access depth – users would have the choice of access depth, which may be to
the National Balancing Point or may be limited to local access only.
Duration of access – users would have a choice, whereby access rights would
be based on the ability to use the system up to the level of the capacity of the right
for a specified duration which could be a Settlement Period or for a number of
Settlement Periods over more than a year.
Granularity of access – users could choose a high level of granularity up to
individual Settlement Periods.
User commitment for connection – under this package a new connectee
seeking connection to the GB electricity network would be required to provide user
commitment security for shallow connection charges. These connection charges
would relate to specific assets required to connect the user to the wider electricity
network. The new connectee would retain the liability to pay for the connection
over the lifetime of the relevant assets.
User commitment for wider reinforcement – the new connectee would provide
security for wider network reinforcements that are required as a result of the new
connection. The liability for these wider network securities would fall away once
the new connectee was connected to the network (i.e. once the connection was
energised and operational).
Firm access – all uses would have a choice of firm access. Firm capacity rights
could be either financially firm and/or physically firm. Firm financial rights would be
associated with a level of compensation for the firm rights if the network is
unavailable via an extended Balancing Mechanism.
Non-firm access – users would have the option of choosing non-firm access. This
would result in them paying much lower locational ongoing usage charges
compared with firm access. This is because when users choose non-firm access,
they would not be compensated for being constrained off to manage network
constraints and the network company would not need to incur the network
reinforcement cost which would otherwise have been needed. Network companies
would be required to identify congested parts of the network in advance of usage
(if not, users would be penalised for not anticipating congestion which cannot be
forecast).
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Changing access rights short-term – there may be some form of special short-
term access product for users who wish to change their contracted access within
year. This product would be at less attractive prices compared with contracting for
access in advance in order to encourage users to contract in advance.
System operation – operational signals are provided by an extended Balancing
Mechanism. All users are entitled to participate in the Balancing Mechanism, either
directly, or via an aggregator. Participation would only be compulsory for larger
users and on an opt-in basis for smaller users. Generators would post physical
notifications of the capacity they expect to generate along with bid and offer prices
for reducing or increasing that generation, with a similar approach used for
demand and demand side response.
9.15 Under this package, new arrangements would be needed for connection at the
distribution level, with alignment between connection arrangements at transmission and
distribution. This approach would require substantial changes to charging arrangements
for both transmission and distribution and a consistent definition of nodal capacity across
both transmission and distribution to derive locational marginal signals across zones.
The charging model would need to reflect the dual drivers of network investment cost,
firstly to ensure security of serving demand and secondly to ensure the economic
transport of power. The new charging methodology would also be required to calculate
price signals to reflect the multiple permutations of potential options available to users
to ensure opportunities to inefficiently arbitrage between options and prices are avoided.
Additionally, careful package design will be required to ensure that the benefits delivered
through the additional optionality are of advantage to both users and the system. There
would need to be consideration regarding how an extended Balancing Mechanism
approach could best be implemented for smaller users.
Package Three: Emphasis on Bilateral Trading and an Extended Balancing
Mechanism (including cluster combinations C1-A, C2-B and C2-D)
9.16 Under this package, network companies would be the network capacity setter and price
taker, which offer fixed network capacity and leave the market to allocate and reallocate
rights to those who value them most.
9.17 There would be relatively low optionality, because trading requires a well-defined
product to trade – if users had the option of changing their arrangements themselves,
they would not need to trade it, so there would be no market.
9.18 In developing these arrangements the network company would need to calculate
appropriate cost-reflective exchange rates to ensure that, even after trading, all users
continue to be exposed to cost-reflective price signals regarding investment, avoiding
opportunities for users to arbitrage or game charging arrangements through trading
opportunities to the detriment of other users
9.19 This package would require substantial change of the existing arrangements.
9.20 Figure 17 gives a representation of package three.
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Figure 17 – Emphasis on bilateral trading and an extended Balancing Mechanism
9.21 The features of this package are described below:
Initial allocation – network companies would release capacity rights based on the
availability of firm capacity rights across the wider transmission and distribution
networks. Capacity rights would be fully trade-able with other users10. Users may
be able to acquire rights from the network company only at specific times as part
of discrete initial allocation releases (first come first served or connect and manage
or some competitive process (e.g. competitive tender)).
Locational investment signals – locational investment signals would be
determined by the value of access to users at particular locations. This would arise
from a competitive approach of allocating access. Alternatively a form of charging
model could be used to calculate locational prices users would pay to purchase
initially allocated access from the network company within a particular release.
Access depth – no optionality, with all users having access to the National
Balancing Point.
Duration of access – firm capacity rights would be based on the ability to use the
system up to the level of the capacity of the right(s) for a specified duration which
could be a Settlement Period or for a number of Settlement Periods over more
than a year.
Granularity of access – users can trade at a high level of granularity up to
individual Settlement Periods.
User commitment for connection –a new connectee seeking connection to the
GB electricity network would be required to provide user commitment security for
shallow connection charges. These connection charges would relate to specific
assets required to connect the user to the wider electricity network. The new
10 There is a key question as to whether the capacity rights at one location are equivalent to the capacity rights at another location, or whether some form of ’exchange rate’ is required, set by the network company, to achieve equivalence of capacity rights across a network
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connectee would retain the liability to pay for the connection over the lifetime of
the relevant assets.
User commitment for wider reinforcement – the new connectee would provide
security for wider network reinforcements that are required as a result of the new
connection. The liability for these wider network securities would fall away once
the new connectee was connected to the network (i.e. once the connection was
energised and operational).
Firm access – users would have the choice of firm access. Firm capacity rights
could be either physical and/or financial:
o Physical rights would be subject to suitable anti-hoarding measures such as
use it or lose it.
o Financial rights would be associated with a level of compensation for the firm
rights if the network is unavailable (i.e. reliability options).
Non-firm access – users would be able to choose to use non-firm capacity to
access the system. However, users would be required to curtail operations in the
event that congestion on the relevant part of the network occurred. Network
companies would be required to identify congested parts of the network in advance
of usage (or else users would be penalised for not anticipating congestion, which
cannot be forecast).
Changing access rights medium to long term – once connected, the new
connectee would become an existing user with the maximum import or export
capacity at that location set out in a Connection Agreement. Existing users would
procure additional capacity rights by either by:
o purchase from the network company who would release capacity rights into
the wider market; or
o acquisition of rights in bilateral traded markets or through market platforms.
Changing access rights short-term – users would be able to fine tune their firm
capacity holdings through the use of a ‘capacity balancing mechanism’ which
operates close to real-time. The capacity balancing mechanism would enable
users to acquire incremental rights or sell rights that reflect their operational
requirements. A user would be able to hedge congestion costs through the
capacity balancing market. Since the market will operate close to real-time the
value of capacity will be closely linked to the short run operating costs of the
electricity system (i.e. the price of electricity on traded markets).
System operation – the network company would be able to buy back rights in the
event that there is significant congestion of the relevant network. Users would be
able to submit bids and offers to sell or buy capacity through the capacity balancing
mechanism. Anti-hoarding measures may be required to ensure that users cannot
exercise locational market power.
9.22 Under this package, new arrangements would be needed for connection at the
distribution level, with alignment between connection arrangements at transmission and
distribution. Arrangements would be needed to facilitate the trading of capacity rights
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either bilaterally or through traded markets, with appropriate anti-hoarding measures
introduced. In order to enable such trading, import and export capacity rights would need
to be explicitly stated in Connection Agreements. A new approach would also be needed
to manage congestion which allows for the exchange of access rights close to real-time.
Package Four: Emphasis on Time of Use Signals with no Contracted Access
(including cluster combinations C1-A and C2-A)
9.23 Under this package, network companies would be the price setter and capacity taker,
meaning the network company has little or no control of user behaviour, other than
setting time of use price signals based on a forecast of how the network company
expects different users to respond in the way which is consistent with a secure network.
9.24 There would be an emphasis on users paying for what they use instead of contracting
for a particular access product in advance.
9.25 When determining ongoing usage charges, the network company would not take into
account what type and where a user is, but would simply set a price for a particular time
and leave users to use what they want, when they want.
9.26 This could be based on incremental change of the existing arrangements.
9.27 Figure 18 gives a representation of package four.
Figure 18 - Emphasis on time of use signals with no contracted access
9.28 The features of this package are described below:
Initial allocation – initial allocation would be on the basis of usage charges on a
first come first served basis. Emphasis would be on users paying for what they
use instead of contracting for a particular access product in advance.
Locational investment signals – the choice of where to connect to the wider
electricity network would be determined by the locational network tariffs applied
on a similar basis to both generation and demand. These would be derived from
a tariff model that is applied to both the transmission and distribution networks.
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The tariffs would be on a zonal basis, with the zones related to collections of nodes
on the system with similar long run marginal cost characteristics.
Access depth – users would have the choice of access depth, which may be to
the National Balancing Point, or may be limited to local access only.
Duration of access – access lifespan is evergreen, so users would not have to
choose between different options of fixed durations. This is consistent with the
approach that users do not need to contract for specific access in advance, but
simply pay for what they use.
Granularity of access – there would not be any options regarding granularity,
because users would not have to contract in advance for particular levels of
access, so can instead use as much capacity as they want, when they want.
User commitment for connection – under this package a new connectee would
be required to provide user commitment security for a shallow connection charge.
This charge would relate to the specific assets required to connect the user to the
‘wider electricity network’ (a consistent definition would be required that relates to
both the transmission and distribution networks). The user would retain the liability
to pay for the connection over the lifetime of the relevant assets.
User commitment for wider reinforcement – the new connectee would provide
security for wider network reinforcements that are required as a result of the new
connection. The liability for these wider network securities would fall away once
the new connectee was connected to the network (i.e. once the connection was
energised and operational).
Firm access – there is no concept of financially firm access. Since users would
simply pay for what they use, users would not have a contractual access product,
so cannot have firm access.
Non-firm access – all users are non-firm. Users would pay for what they use, so
they would simply benefit from avoiding having to pay time of use charges if they
did not use the system at a particular time.
Changing access rights medium-term to long-term – there would be no need
for users to engage in contractual changes to their access rights in the medium-
term to long-term, because users would simply pay for what they use.
Changing access rights short-term – there would be no need for users to
engage in contractual changes to their access rights in the short-term, because
users would simply pay for what they use.
System operation – existing users would be subject to strong signals that reflect
the close to real-time operating costs (in £ per MWh) for the total system (for
example costs in each Settlement Period). These signals would be derived ex ante
and designed to influence user behaviour and in particular user dispatch.
Operational signals would be designed to discourage usage of the electricity
network when it is highly congested. This means that user costs would be high at
such times reflecting the higher costs of operating the network (and resolving
74
congestion). Under a generation driven constraint, generation users could only
avoid such costs by curtailing output; similarly under a demand driven constraint,
demand users could only avoid such costs by curtailing demand. At other times
costs for using the network would be relatively small.
9.29 Under this package, new arrangements would be needed for connection at the
distribution level, with alignment between connection arrangements at transmission and
distribution, with a new charging model approach and a consistent definition of nodal
capacity needed across both transmission and distribution to derive locational marginal
signals across zones. This new approach would be required to have the capability to
provide an ex ante price signal to reflect the cost of congestion at different locations.
Summary 9.30 The plausible packages presented in this report are representative of different ways in
which network access and charging arrangements might be developed. They are
included as a starting point for discussion and it is recognised that there are many other
options that have not been explored and indeed alternative ways in which each of the
packages could be further developed and refined.
9.31 Further review of plausible packages is recommended, combining individual options into
a single universal methodology combined with a more detailed assessment regarding
how different packages are best reflected through the choice of charging models and
tariff structures.
9.32 Practical package design details should be considered, regarding how particular options
may work in practice, such as:
targeted auctions for initial allocation;
short-term and long-term trading;
auctions for initial allocation;
use of an extended Balancing Mechanism;
the creation of markets for trading access;
safeguarding core or basic capacity for domestic ;
options for depth of access – regarding access that is less than to the National
Balancing Point;
treatment of unused capacity; and
the connection charging boundary.
9.33 Some important questions to consider when assessing different structural combinations
of options include:
For a package based on contracted capacity with a low level of optionality for
users, could this “one size fits all” type of access product sufficiently meet the
needs of different users?
For a package which includes a high degree of optionality for users, to what degree
could the network company calculate price signals to reflect every permutation of
options to avoid opportunities for users to inefficiently arbitrage between different
options and prices? Otherwise, it may be possible that greater optionality could
deliver value to the users making the choices, but possibly to the detriment of other
users and may not necessarily deliver additional value to the system.
75
For a trading based approach, to what degree can the network company calculate
appropriate cost-reflective exchange rates to ensure that, even after trading, all
users continue to be exposed to cost-reflective price signals regarding investment,
avoiding opportunities for users to arbitrage or game charging arrangements
through trading opportunities to the detriment of other users?
For an approach based on time of use tariffs, could this provide an effective signal
to reflect the drivers of network investment costs, while also providing network
companies with sufficient control to efficiently manage network congestion in the
absence of operational tools such as a Balancing Mechanism, or active network
management?
76
10. Summary and Recommended Further Work 10.1 The work of the Task Forces described in this report is summarised in this section,
followed by some further considerations.
Report Section Summaries
Cluster One – Influences User Investment (Section 4)
10.2 A greater alignment of the principles, methodologies and arrangements for connection
and ongoing usage charging at transmission and distribution levels is desirable to avoid
boundary issues. This could be achieved by:
a common shallow connection charging boundary across all voltage levels in
transmission and distribution to encourage flexible responses from all connected
users (i.e. connection charges would just include extension assets with
reinforcement costs treated through ongoing usage charges); and
locational ongoing usage charges at transmission and distribution EHV only
generated by complimentary methods/models; and an HV/LV representative
model adjusted for locational issues e.g. a generation dominated network.
10.3 A shallow connection charging boundary facilitates the use of flexibility by providing a
direct price signal to compare the cost of flexibility against network asset solutions, and
also reduces the risk of a barrier to some new users connecting which can be created
when connection charges are high. A shallow connection charging policy on distribution
networks would require more locational ongoing usage charges further down the
network. Applying a shallow connection charging policy further down the network will
therefore depend on how feasible it is to apply locational ongoing usage charges at lower
voltage levels whilst applying appropriate protection to more difficult to serve
communities. Whilst greater granularity can be more cost-reflective it can also result in
more volatile charges which are hard to predict and hence less likely to influence
behaviour. Some users may prefer the stability of charges achieved through a deeper
connection charging boundary than the potential volatility of ongoing usage charges if
the connection charging boundary were shallow. From a practical implementation point
of view, it may be preferable to limit locational signals to EHV connections, and hence a
shallowish connection charging policy may remain appropriate at HV and LV.
10.4 There are likely to be significant issues with transitioning to shallow connection charging
arrangements for all voltage levels. The requirement to incorporate grandfather rights
for existing users would need to be considered, potentially delaying the benefits of the
change and giving some users a disincentive to update connection arrangements, for
example, to release underutilised capacity.
10.5 To reduce the risk of stranded asset costs, it is in the interests of all parties to ensure
that, where network capacity is increased in response to a user request, that increased
capacity is utilised. User commitment until at least the time of connection and potentially
for a period beyond connection would reduce the risk of stranded asset costs, but could
be burdensome to deliver for a high volume of customers (i.e. if applied at all voltage
levels). Any introduction of post-connection user commitment would need to be
assessed against the cost of users obtaining the financial backing required to provide
such commitment, which may be disproportionate to the benefit delivered.
77
Cluster Two – Influences User Operations (Section 5)
10.6 Reallocation of access rights could offer benefits in certain scenarios. Providing users
with a wide range of access choice and the ability to vary this choice through the lifetime
of their connection will allow users to connect quickly (ahead of wider network
reinforcement) and to trigger efficient reinforcement at a time when user requirements
indicate this is appropriate.
10.7 Within this, tools that allow fine tuning of real-time user operations can have an important
role to play in network charging, allowing control in a way which is not possible through
providing time of use price signals alone. There are many different ways in which this
fine tuning could be achieved. One option may be to extend to more voltage levels and
users a structure similar to the current transmission network’s Balancing Mechanism
where users are compensated for their actions to balance the system. Another option
may be something closer to distribution active network management arrangements
where users are not currently compensated for constraints.
10.8 Reallocation of capacity through market-based or bilateral trading is likely to need to be
supported by network planning studies which ensure sufficient network capability and
exchange rates, particularly for trading across wider geographic areas. Ensuring a level
playing field between larger and smaller users is likely to be important if bilateral trading
is implemented. Whilst auctions were not favoured by most Task Force members, they
could be seen as a potential way of valuing and/or trading constraint obligations (with
the transfer value between locations needing to be established by the network
company).
10.9 Time of use charges can also have an important role to play in efficiently operating the
network as the costs of owning and operating a network vary across the day and year.
Dependence on only user responses to time of use charges may not be sufficiently
resilient to prevent reinforcement to meet security of supply standards.
10.10 It is important to consider that different types of operational signal may be better suited
for different types of user or for different situations. However, how such different user
types are defined may be complex and care is needed to make sure distortions are not
created.
10.11 Reform of how user operations are influenced through charging must include
consideration of feasibility and possible unintended consequences of the options being
considered. This includes mechanisms to avoid gaming, inefficient interactions between
signals, excessively complex signals to which users cannot respond effectively as well
as any unintended social or other consequences if such reforms lead to more volatile
signals.
10.12 It is also important to minimise distortions which may arise if two or more different forms
of price signal may provide conflicting operational signals, or provide gaming
opportunities as this could distort user operations and lead to less efficient outcomes.
Tariff Design and Charging Models (Section 6)
10.13 The choice of tariff design and charging model chosen is mainly dependant on the
decisions made regarding cluster one and cluster two. Task Force discussions have
highlighted this choice as an implementation decision as there are a wide range of tariff
elements and models that can be used to complement the cluster one and cluster two
decisions.
78
10.14 Whilst the advantages and disadvantages in section 6 have mainly been focussed on
an absolute basis, rather than relative, it is important to consider further analysis of these
pros and cons relative to the cluster one and cluster two decisions once these have been
made.
10.15 Extending time of use tariffs to all users would be beneficial as it extends the price signal
to all users and drives innovation as smaller users become incentivised to reduce their
costs. In order for any benefit to be derived from network time of use tariffs, it is
necessary for these to be passed through to end users. Moving to a seasonal price
would allow network companies to set more cost-reflective charges for users. The
visibility of appropriate data to allow users to forecast future charges is seen as vital to
any of the proposed solutions.
10.16 The development of active network management schemes could provide incentive for
profiling capacity at distribution level, similar to the Balancing Mechanism at
transmission.
10.17 The design of future tariffs might need to reflect the use of core and non-core capacity;
however this is also true of a number of other elements which could be taken forward as
part of any change to network access arrangements.
10.18 There is merit in trying to rationalise and increase commonality across transmission and
distribution to avoid distorting demand and generation users’ decisions to connect at
distribution EHV or transmission respectively (i.e. avoiding perverse incentives), and to
ensure that users are exposed to the costs they impose on the whole system and just
the network to which they are connected. However, locational charging at HV and LV is
not yet possible or practical and could have unintended consequences for some users.
It will need to be determined, if changes are felt to be appropriate, whether this should
be a single model covering all voltages or two models which reflect the different
arrangements.
Access Properties (Section 7)
10.19 There was a wide range of views expressed by Task Force members on network users’
preferences for access rights. Although there was little or no preference for bespoke
arrangements, the responses indicated they value choice across all the other access
characteristics (i.e. depth, lifespan time of use, and level of firmness). Regardless of the
options selected under each of the access properties, there will be a need to ensure that
the charges associated with each combination are cost-reflective.
10.20 It was noted that the introduction of financially firm arrangements at the distribution
network level would be a significant change likely requiring careful definition,
amendment to security standards and more importantly acceptance from other network
users that they would fund any unavailability payments.
10.21 Core and non-core access rights for domestic and small commercial users connected
at LV should be considered (i.e. a basic capacity for essential services with options to
buy additional access for things like electric vehicle charging).
Initial Allocation of Access (Section 8)
10.22 There will always be an element of first come first served when initially allocating
capacity to new users, which can be further developed by adopting queue management
and/or connect and manage mechanisms at transmission and distribution, but there may
79
be value in applying targeted auction or market based approaches in specific
circumstances to improve the efficiency of connecting new users, for example managing
access allocation behind constraints. However universal auctions are not recommended
by the Task Forces due to the inability to match gate closure with the timing of users’
projects and also the risks of unintended consequences from new users not securing
the access they need from the auction process.
Plausible Packages (Section 9)
10.23 The Task Forces created four plausible packages as a starting point for discussion about
future approaches and further review of packages, which combine individual options into
a single universal methodology, would benefit from further consideration. This should be
combined with a more detailed assessment regarding how different packages may be
best reflected through the choice of charging models and tariff structures.
Further Detailed Considerations 10.24 The broad terms of reference for the CFF Access and Forward Looking Charges Task
Forces were ambitious, especially given the relatively short timescales allocated to
complete the work. This has necessarily meant that the Task Forces have only
considered issues at a relatively high level and it has not been possible to carry out in
depth or quantitative analysis at this stage. The Task Force membership encompassed
a wide range of different experience and expertise from across the industry, which has
enabled a better understanding of potential advantages and disadvantages of different
options for change. This work should be considered the start of an industry discussion
which is expected to be further developed through Ofgem’s forthcoming consultation.
10.25 The work has identified many key issues and questions which the Task Forces consider
would benefit from further consideration. These include issues such as:
Quantitative assessment of the key drivers of costs on both transmission and
distribution networks such that the forward looking charges are cost-reflective on
an absolute basis to create a level playing field that is sustainable. This work
should draw a clear link between the RIIO framework which defines what the costs
actually are (and how they can vary and over what timescales) and the charging
framework which recovers those costs. Such work will allow a transparent regime
where network users can see areas where their decisions will save costs on the
networks.
Practical design details regarding how particular options may work in practice in
the distribution and transmission contexts, such as:
o targeted auctions for initial allocation and other options for short-term (e.g.
an extended Balancing Mechanism) and long-term trading;
o the definition and application of core or basic capacity for domestic and small
commercial users;
o the rollout and associated reinforcement costs for new low carbon
technologies;
o the treatment of unused capacity including in relation to the application of
user commitment at distribution voltages;
o safeguarding newly connecting and the wider body of users from the high
costs of serving remote or sparse networks; and
o users’ behaviours in response to cost and price signals outlined in various
options.
80
The application of use cases to assess how feasible the access right preferences
described by network users would work together in practice across both
transmission and distribution networks and are aligned to cost-reflective charges;
for example:
o depth of access (i.e. the option for local access only rather than full access
to the national energy market);
o standardisation of access (i.e. is it practical to offer only bespoke products);
and
o financial firmness (i.e. how the option for financial firmness would work for
generation connected to distribution networks recognising the necessary
impact on connection charging, and connection and operating policies and
standards).
Particular design features which may be able to mitigate some of the potential
disadvantages identified in the work.
Implementation and transitional arrangements including the possibility of phasing
or grandfathering will also need to be considered.
10.26 The Task Forces have not been able to evaluate whether different approaches produced
different treatment for users such as generators, behind the meter assets, large
commercial users, or small domestic users and so any further work would benefit from
looking into this aspect. This should take into consideration outcomes for flexibility
service providers and ensure that vulnerable users are treated appropriately and a
balance needs to be struck between meeting the needs of existing compared with future
users.
10.27 The Task Forces noted the potential broader impacts and interactions arising from
different options which would need to be assessed, including:
how far options would better facilitate independent participation by users or would
require stronger reliance on intermediaries;
the relationship between the options considered and design standards (i.e. the GB
Security and Quality of Supply Standard (GB SQSS) which applies to transmission
and Engineering Recommendation P2/6 which applies to distribution);
how the signals sent by network charges would interact with the wholesale price,
Balancing Mechanism and Capacity Market;
how far different options could be susceptible to gaming;
how the different options considered could interact with the potential creation of
local markets; and
how the different options could impact on the owners and operators of private
networks, independent licensed distribution networks and offshore transmission
networks.
10.28 The Task Forces note the potential impact and linkages to other programmes with a
direct relation to this work, including:
a quantitative impact assessment of the scale of existing issues requiring to be
addressed, which is being develop by Baringa. Draft interim results of Baringa’s
work were made available to the Task Force. It is expected that this will help to
inform prioritisation of future work;
the Targeted Charging Review;
the Energy Networks Association’s Open Networks programme;
81
the development of RIIO-2; and
ongoing changes to retail competition.
10.29 The Task Forces wish to raise that whilst the disadvantages of options which have been
put forward by Task Force members and presented in this paper may cover some of the
consequences of implementing a given option, this is not a comprehensive study and
there is a risk of adverse unintended consequences. Risk of unintended consequences
of the implementation of any changes taken forward should be fully considered.
10.30 In the later stages of Task Force activity, Ofgem highlighted that, for distribution network
companies, the recovery of network costs incurred in the provision of flexible and active
network management connections had links to wider policy questions, many of which
are subject to debate across the industry and within the scope of access reform. The
Task Forces started working on the topic and discussed some pertinent aspects for
further consideration. However, because active network management can be used to
manage a broad range of circumstances, ranging from fairly straightforward individual
connections to a wide area active network management scheme, as well as having a
key role in the facilitation of future Distribution System Operator models, it was agreed
that the topic required more detailed consideration across a range of potential charging
approaches. Discussions with Ofgem concluded that thinking on the topic should be
developed further within the Energy Network Association’s Open Networks project,
specifically under Workstream 4.
82
11. Glossary Term Definition
Active Network Management (ANM) system
Control systems that manage generation and load for specific purposes. This is usually to keep system parameters (voltage, power, frequency) within predetermined limits.
Balancing Mechanism A trading system run by the Electricity System Operator that allows it to agree actions with generators to increase or decrease generation.
Connection Agreement An agreement between a network company and a user which provides that the user has the right for its installation to be connected.
Connection and Use of System Code (CUSC)
CUSC constitutes the contractual framework for connection to, and use of, the national electricity transmission system.
Distribution Connection and Use of System Agreement (DCUSA)
The DCUSA is a multi-party contract between the licensed electricity distributors, suppliers, generators and Offshore Transmission Owners of Great Britain. It is a requirement that all licensed electricity distributors and suppliers become parties to the DCUSA.
Distribution Network Operator (DNO)
An electricity distributor that operates one of the 14 distribution services areas and in whose electricity distribution licence the requirements of Section B of the standard conditions of that licence have effect.
Distribution System Operator (DSO)
The operator of the Distribution System.
Electricity System Operator
An organisation entrusted with ensuring supply and demand are balanced second to second and in the longer term, and managing power flows across the network safely and reliably. National Grid is the Electricity System Operator for Great Britain.
Engineering Recommendation P2/6
The security of supply standard for demand connected to distribution networks.
Extra-High Voltage (EHV) Nominal voltages of 22kV and above.
GB Security and Quality of Supply Standard (GB SQSS)
Sets out the criteria and methodologies for planning and operating the GB Transmission System.
Grid Supply Point (GSP) A metered connection between the National Grid Electricity Transmission system and the DNO’s distribution system at which electricity flows to or from the Distribution System.
High Voltage (HV) Nominal voltages of at least 1kV and less than 22kV.
kVA MVA
Kilovolt ampere. Megawatt ampere.
kVArh Kilovolt ampere reactive hour.
kW MW
Kilowatt. Megawatt.
kWh Kilowatt hour (equivalent to one “unit” of electricity).
Low Voltage (LV) Nominal voltages below 1kV.
National Balancing Point A virtual trading location for the sale, purchase and exchange of electricity.
83
Ofgem Office of Gas and Electricity Markets – Ofgem is governed by GEMA and is responsible for the regulation of the distribution companies.
Settlement The determination and settlement of amounts payable in respect of charges (including reconciling charges) in accordance with the BSC.
Settlement Period Each day is split into 48 Settlement Periods, with Settlement Period 1 equivalent to 00:00 to 00:30.
Supplier An organisation with a supply licence responsible for electricity supplied to and/or exported from a metering point.
TERRE
Trans European Replacement Reserves Exchange (TERRE) is the European implementation project for exchanging replacement reserves in line with the Guideline on Electricity Balancing.
Unmetered Supplies
Exit points deemed to be suitable as unmetered supplies as permitted in the Electricity (Unmetered Supply) Regulations 2001 and where operated in accordance with BSC Procedure 520.
Use of System Charges Ongoing charges which are applicable to those parties which use the Distribution and Transmission Systems.
85
Appendix Two – Code Objectives and Assessment Criteria
12.2 Figure 19 shows the applicable Connection and Use of System Code (CUSC) and Distribution, Connection and Use of System Agreement
(DCUSA) objectives:
Figure 19 - Applicable CUSC and DCUSA Objectives
12.3 Figure 20 shows the assessment criteria, and the objectives to which the Task Forces believe they relate.
Figure 20 - Assessment criteria mapped to DCUSA and CUSC objectives
High Level
Objective
Licence
Compliance1
That compliance by each DNO Party with the Charging Methodologies facilitates the discharge by
the DNO Party of the obligations imposed on it under the Act and by its Distribution Licence
Effective
Competition(a)
That compliance with the use of system charging methodology facilitates effective competition
in the generation and supply of electricity and (so far as is consistent therewith) facilitates
competition in the sale, distribution and purchase of electricity
2
That compliance by each DNO Party with the Charging Methodologies facilitates competition in
the generation and supply of electricity and will not restrict, distort, or prevent competition in
the transmission or distribution of electricity or in participation in the operation of an
Interconnector (as defined in the Distribution Licences)
Cost Reflectivity (b)
That compliance with the use of system charging methodology results in charges which reflect,
as far as is reasonably practicable, the costs (excluding any payments between transmission
licensees which are made under and in accordance with the STC) incurred by transmission
licensees in their transmission businesses and which are compatible with standard condition
C26 (Requirements of a connect and manage connection)
3
That compliance by each DNO Party with the Charging Methodologies results in charges which,
so far as is reasonably practicable after taking account of implementation costs, reflect the costs
incurred, or reasonably expected to be incurred, by the DNO Party in its Distribution Business
Developments in
Network
Businesses
(c)
That, so far as is consistent with sub-paragraphs (a) and (b), the use of system charging
methodology, as far as is reasonably practicable, properly takes account of the developments in
transmission licensees' transmission businesses;
4
That, so far as is consistent with Clauses 3.2.1 to 3.2.3, the Charging Methodologies, so far as is
reasonably practicable, properly take account of developments in each DNO Party’s Distribution
Business
Compliance with
European
Regulation
(d)Compliance with the Electricity Regulation and any relevant legally binding decisions of the
European Commission and/or the Agency5
That compliance by each DNO Party with the Charging Methodologies facilitates compliance
with the Regulation on Cross-Border Exchanges in Electricity and any relevant legally binding
decisions of the European Commission and/or the Agency for the Co-operation of Energy
Regulators
Effeciency of
Implementation(e)
Promoting efficiency in the implementation and administration of the system charging
methodology6
That compliance with the Charging Methodologies promotes efficiency in its own
implementation and administration
n/a
Relevant Distribution Connection and Use of System Agreement (DCUSA) Charging Objective
(Applicable to Distribution)
Relevant Connection and Use of System Code (CUSC) Charging Objective (Applicable to
Transmission)
Assesment Criteria Primary Related Objective Secondary Related Objectives
1 Efficiently meet the essential service requirements of network usersDevelopments in Network
BusinessesLicence Compliance
2 Optimise capacity allocation Effective Competition
3Ensure that price signals reflect the incremental future network costs and benefits that can be
allocated to and influenced by the actions of network usersCost Reflectivity Effective Competition
4 Provide a level playing field for all network users Effective Competition
5Provide effective network user price signals, i.e. price signals which can be reasonably
anticipated by a user with sufficient confidence to allow them to take actionEffective Competition Cost Reflectivity
6 Appropriately allocate risk between individual network users and the wider body of users Effective Competition
7 Support efficient network developmentDevelopments in Network
Businesses
8 Be practical Effeciency of ImplementationCompliance with European
Regulation
9 Be proportionate Effeciency of Implementation
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Appendix Three – Advantages and disadvantages of Framework Scenarios as Expressed by Task Force members
12.4 High emphasis on auctions/trading
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Larger users - potential to optimise allocation of scarce capacity (i.e. behind a constraint).
- A large body of aggregators, offtakers and suppliers could compete to create portfolios and optimise capacity allocation.
-There is no fixed network capacity to allocate - Available network capacity depends on the mix of users.
-Interaction with Capacity Market and Balancing Services might make cheapest flexible resources more expensive.
-Generators - risk of 'pricing out' of the market for smaller players, so may not optimise in terms of finding most efficient, but rather find those
with deepest pockets
-Smaller users - little or no benefit; will be so reliant on assumptions made by intermediaries with the need for safeguards to avoid undesirable
consequences for auction losers.
- Auctioning capacity has many issues; it is unclear how an auction mechanism involving individual parties could optimise capacity
4 - Provide a level
playing field for all
network users
- If auctions are market wide (a big if!), all users are competing for equivalent products, so a level playing field would be created.
- Supplier may be able to offer cheaper fixed rate tariffs by buying large blocks of access
- Risk of gaming, e.g. Some participants may be better placed to carry out speculative capacity bids to buy up capacity in order to later sell on
secondary market. Equivalent to ticket touts for events. Difficulty of drawing line between 'large' and 'small' for the purpose of smaller user
safeguards.
- Smaller users - Likely to need significant safeguards/'carve-outs' resulting in a distortion of the 'pure' level playing field created by exposing all
users to the risk of losing in the auction.
- Potential for large users to game the system, and so make smaller users uncompetitive.
- Could make Standard Variable Tariffs more expensive as it becomes difficult for suppliers to forecast customer numbers in regions under
variable tariffs (cannot purchase access in advance as unknown customer base)
- Unlikely to create clear long term signals
- Risks over rewarding network users who are mobile
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Assuming auction takes place behind a constraint, would provide strong locational cost signals- Very difficult for users to respond to price signals
- Auction clearing prices likely to be highly volatile and difficult to predict, making this a poor investment signal.
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Smaller users - if protections are not put in place for smaller users, places disproportionate risk on individuals, of either being exposed to high
prices if auction clears at a high price or of losing network access if they (or an intermediary working on their behalf) loses in the auction
- Larger users - if protections are put in place for smaller users, places disproportionate risk on larger users who could be left to 'divvy-up'
remaining capacity after allocation to smaller users
- Impact of loss of connection on individual users could be immense
- Likely to inefficiently allocate risk
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Potential to provide highly locational price signals.
- An appropriate reserve price would ensure prices never fell below incremental costs of providing capacity
- Higher costs will indicate constraints in a region, and users could respond by investing in new kit or reducing usage
- Auction price will not reflect 'incremental future costs and benefits that can be allocated'; rather it will reflect the willingness to pay of the
auction winners
- Potential conflict between holding a competitive auction and giving long-term locational signals
1 - Efficiently meet
the essential service
requirements of
network users
- From an idealistic standpoint, this option has the potential to improve capacity allocation and so efficiently meet longer term requirements by
minimising expenditure.
- Portfolio approaches could allow users to share network access over different times by buying together as a group or under a 'neat' supplier
portfolio
- Users will be prepared to pay up to the value of their business/project to obtain network access, even then they may fail to secure access. This
means businesses (hospitals/schools?) as well as generation assets could close due to failure to secure network access.
- Smaller users - unlikely to meet essential requirements without significant safeguards
- Larger demand users - potentially under-values stability; industrial users would not see a regular auction as an efficient means of meeting their
requirements which are inherently stable and long term
- Due to practical issues with holding an auction, this is unlikely to be an 'efficient' means of meeting essential service requirements
7 - Support efficient
network development
- Larger users - demand in each auction (i.e. the differential between the clearing price and the reserve price, or the number of bidders) will
provide network operators with a signal of where additional capacity is needed
- Auctions provide a poor price signal for network investment - DNO/TO may have poor visibility of current and future bid stack, so very difficult
for DNO/TO to predict what the impact will be of a given network investment on future auction clearing prices.
- Lumpiness of network investment -Will tend to exacerbate the volatility of auction clearing prices
- Smaller users - safeguards required to ensure user's essential requirements are met are likely to render this option similar to the status quo for
information provided to the network operator
- Auctions do not provide for strategic planning that is most cost effective
8 - Be Practical
- Practically very difficult to implement. There is not a single national network capacity, but a myriad of different available capacities. Available
capacity will vary by location and by mix of user type. Available capacity in some areas will also depend on the success of users in other areas.
Therefore the locational mix of successful users is subjective and indeterminate.
- If auctions are more targeted, potentially practicality improves but this introduces level playing field concerns
- Would require changes to Capacity Market arrangements to avoid conflict
- Too many issues to make this a practical option for demand customers
9 - Be Proportionate
- Auctions fail to address the issue with current arrangements relating to increasing congestion on networks causing a need to provide more
efficient price signals to smaller users (Inc. EV) , then it is this very group for which auctions are less appropriate and least effective.
- Minimal benefits derived from major administrative effort
- Too many issues make this disproportionate
Assessment Criteria
High emphasis on auctions/trading:
Access products are well-defined (including being financially firm) and purchased via auctions, with scope for re-sale. Charging models still used to set robust reserve prices, with potential changes needed to ensure they reflect differential value of access adequately.
Effe
ctiv
e C
om
pet
itio
nD
evel
op
men
ts in
Net
ow
rk B
usi
nes
ses
Effi
cien
cy o
f Im
ple
men
tati
on
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12.5 High emphasis on access right choices
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Larger users - potential for a significant improvement to capacity allocation by offering a greater range of products as standard (e.g. time
restricted off-peak 'budget' access products)
- Smaller users - potential for some benefit for users wanting 'premium' products (e.g. the ability to charge EV at peak time)
- Generators - more scope for (flexible) sharing of access rights between non-coincident generation technologies
- Depending on which access products are created, this does have the potential to effectively allocate capacity
- Smaller users - likely to be reliant on significant assumptions on the behaviour of each end user. For a disengaged user this could simply be a
more administratively involved means of maintaining the status quo.
- Smaller users - may create a perverse incentive to avoid smart metering and/or avoid informing the network operator what equipment is
connected to avoid the need for 'premium' access products and instead rely on assumptions on typical demand
4 - Provide a level
playing field for all
network users
- If market wide, all users will be competing for equivalent products, creating a level playing field.
- Larger users - removes a distortion between users who only wish to use the network at off-peak times (but under current arrangements are
required to reserve the capacity they require regardless of when they use it) and users who wish to use the network at peak times. Reserving
capacity at peak drives higher network cost than off-peak which could be reflected in the cost differential between access products
- Smaller users - could be disadvantaged at the expense of larger users who have the resource to engage more effectively and so purchase the
access they need whilst smaller users may find it more difficult to differentiate
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Clear price signals which can be responded to
- Users can reserve/change access rights (many years) in advance and have visibility of what the likely charges associated with those access rights
will be. This enables users to respond to those price signals when making investment decisions.
- Can create clear price signals
- Potential to over-value the provision of access and consequently under-value changes in usage behaviour
- Will still be dependent on network modelling so improvements will be required to address perceived flaws in the current approaches
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- If users pay a cost reflective price for their access right, then they are paying for a level of network access service from the DNO/TO. It is within
the control of the DNO/TO to make decisions regarding network reinforcement which results in higher/lower cost, or degradation of service, so it
is right that users are insulated from this risk.
- Exposes users to some risk by exposing them to the cost of providing (e.g.) peak time access differentiated from the cost of off-peak access.
- Clearly designed products should mean users know what they are buying and the risks they are taking
- Depending on locational granularity, potential for 'premium' access products to become extremely expensive, and potentially over-expose
users to the risk of networks becoming congested, where arguably some of this cost should be shared with the wider body of users
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Network charges are a price for receiving a network access service
- It is relatively straight forward for network charges to reflect the cost to the DNO/TO of providing the network access service.
- May over-value providing access and under-value ongoing usage - e.g. likely to be a limited ongoing signal of the benefit to the network of
using less than the access product purchased
- Will remain dependent on the modelling used to price the available products, which needs to be improved to be more cost-reflective
1 - Efficiently meet
the essential service
requirements of
network users
- When users pay a cost reflective price for network access, they should be able to expect their essential service requirements of access will be
met. It is then appropriate that in the event that service may not be delivered, the user is compensated for that degradation of their service.
- May allow the network operator to effectively allocate capacity based on the access products purchased and so meet long term requirements
efficiently
- With the right products, this could be an efficient approach
- Given the number of products will be restricted, there is a risk that users purchase access products conservatively (i.e. the option which
provides more than they need rather than less) which the network operator must then allow for - leading to unused capacity
7 - Support efficient
network development
- DNO/TO have good visibility (potentially many years) in advance of what access rights different users are going to request - This enables
DNO/TO to effectively plan network investment accordingly
- Potential for better use of existing network through better capacity 'sharing' based on time of use.
- Alongside information from other sources, planning could be strategic
- With the right products, this could be an efficient approach
- Could place incentive on developers to opt for minimum access option, only for network operator to later be required to reinforce to meet the
actual needs of users.
- May require the network operator to 'guarantee' access to the level of the product purchased, resulting in unnecessary headroom.
8 - Be Practical- Transmission - this approach is already closest to existing charging arrangements
- Smaller users would require some means of agreeing the level of access with each end user (or an intermediary working on their behalf),
requiring a huge number of bilateral agreements
- Larger distribution connected users would require more detailed connection agreements specifying more detail on the access product
purchased, and detailed considerations on the consequences of over-use beyond access product purchased
- Would need new planning approach (and software), alongside new criteria to manage risk of stranded assets
9 - Be Proportionate
- Transmission - requires least change and disruption for users
- Larger distirbution connected users - benefits are potentially significant, with relatively small implementation hurdles- Smaller users - major implementation challenges for minimal benefit
Assessment Criteria
High emphasis on access right choices:
Access rights are granted broadly on a first come first served basis, with a range of choice around type of access to maximise use of capacity. Capacity charges reflect impact of different choices on network costs. Changes so that non-firm holders can trade curtailment obligations through a
market-based mechanism.
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12.6 High emphasis on use of system charges
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- No direct impact on capacity allocation, but cost-reflective usage charges have the potential to impact the way in which existing capacity is used
- Predictable pricing signals optimise the dispatch and connection of assets
- As a standalone option this may be less effective at allocating capacity, but combined with access products this could be effective
- TOU price signals may conflict with other short-term mechanisms to allocate capacity such as Balancing Mechanism (BM). Application of both
TOU and BM price signals for the same network may be incompatible, however, conflict may be avoided if users only face one or the other,
instead of both. However, under the BM, users set their own price, therefore any price dispatched under the BM is reflective of that user's value,
which includes costs for network use and access.
- No improvement on the 'implicit' sharing of capacity which exists under the status quo
4 - Provide a level
playing field for all
network users
- With cost-reflective usage charges, each user will face the same charges (for an equivalent unit of energy, i.e. at the same time and location),
creating a level playing field.
- TOU tariffs are easier to avoid, which may cause some distortions and be less fair.
- Potential for volatility in charges overly favouring flexible users
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Dependent on predictability of pricing - if prices and time periods are predictable, users should be in a position to respond.
- Prices could be highly locational and therefore focused on parts of the network that is near to full capacity, providing strong price signals.
- Static TOU tariffs can provide predictable prices which give a clear investment signal
- It would be very difficult for users to forecast what their charge at any given time, or total annual charge will be, therefore very difficult to make
investment decisions.
- Static time of use signals set in advance do not reflect the value or quantity of available capacity at that particular time - So they are an
economically inefficient tool for incentivising user responses.
- It is essential that charges are highly cost-reflective to avoid inefficiencies, which may result in more volatile signals.
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Lower socialisation (e.g. locationally) arguably allocates risk more appropriately - where user behaviour has the potential to avoid costs users
are exposed to strong cost signals; other users are not.
- Cost-reflective charges provide the most robust risk allocation
- Dynamic TOU price signals will be volatile by value and also volatile by timing - This exposes users to substantial risk regarding what their total
annual network charge is going to be, caused by factors outside of their control.
- Prices could be very high in certain time bands - for example if a STOD structure was selected, then could have a high peak price.
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Assuming the calculation of charges is done on a sound basis, charges should accurately reflect costs and benefits which can be allocated to the
behaviour of certain users.
- Sufficient transparency of network conditions and ex post charging allows parties to respond to their pricing signals
- Cost-reflective charges inherently achieve this criteria
- Network investment is generally driven by changes in user capacity, not changes in user profile "use" - If a user happens to reduce their "use" at
a key time in one particular year (therefore reduces its network charges in that year), this does not necessarily reflect the cost of network the
DNO/TO needs to build to serve that user in that, or future years
- Static TOU tariffs are not cost reflective - Because the particular periods of constraint, or high stress on the network are driven by weather and
outturn market conditions, the specific timing of which can not be known in advance.
- Highly cost-reflective charges create risks for some (rural?) customers due to low socialisation of costs
1 - Efficiently meet
the essential service
requirements of
network users
- Potential for user responses to cost signals to reduce long run costs for all network users.
- Charging aggregated portfolios allows suppliers to spread costs across all market participants and offset with local solutions (i.e. generation and
storage), to ensure essential service needs are met
- The essential requirements of customers who cannot respond to cost signals are likely to be charged more under this option. May leave some
customers priced out of the market if prices are very high.
- Particular problem for smaller and/or domestic users; users who are less likely to monitor and respond to TOU electricity market pricing may
receive shocks to their annual network charge if they consume power at the "wrong" time.
- Highly cost-reflective locational charging may disadvantage vulnerable users with low usage, so may require some protections (e.g. minimum
usage) to protect vulnerable users.
7 - Support efficient
network development
- Evolving cost signals will reflect congestion on the network at each time and location, enabling user responses which avoid the need for
reinforcement and improve efficiency.
- Emphasises efficient use of the network
- DNO/TO have poor visibility of what the future demands on the network may be. This provides a relatively poor price signal for network
reinforcement.
8 - Be Practical- User will not be required to make up front assumptions on their future use of the network, so more similar to status quo for end users.
- More complicated and burdensome than existing arrangements. TOU tariffs would need to be more dynamic, varying over time and by location
at sufficient granularity. This would require a significantly more complicated tariff model and require it to be updated many times per day.
- Difficult to send appropriately granular but appropriately stable location and temporal cost signals for the mass market.
- Consumers will need education and good information (e.g. in home display) to be able to respond to pricing signals
- Requires improved network modelling to ensure charges are cost-reflective
9 - Be Proportionate
- Does not require immediate user engagement.
- Benefits of charges that reflect the absolute costs that users impose on the network mean the increased complexity is proportionate
- Would introduce substantial additional complexity for both users and network operators, while delivering price signals which are less effective
at incentivising economically efficient responses.
- Consumers will need education and good information (e.g. in home display) to be able to respond to pricing signals
Assessment Criteria
High emphasis on better usage charges:
Limited changes to access, with reliance on usage charges, with most charges focused on usage at system peaks. Could include more locational charging for constraint costs.
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Appendix Four – Advantages and disadvantages of C1 Combinations as Expressed by Task Force members
12.7 C1-A – shallow connection charging with user commitment
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. Implicit network sharing
2. Shallow boundary facilitates capacity reallocation
3. Zonal requirements are easier to understand than nodal, allowing parties to plan better
1. Weaker penalty for overstating initial requirements post connection (security falls away)
2. Relatively weak locational signal gives weaker incentive on location
4 - Provide a level
playing field for all
network users
1. Lack of large upfront connection costs can help smaller players.
2. Consistent arrangements across T and D give immediate improvements by removing the discrepancy across the T/D boundary
3. Can depend on initial allocation method
1. Securitisation tends to favour larger players who can rely on their credit ratings. Securitisation would be virtually impossible to manage at the
small business/domestic level.
2. Users are treated the same in terms of connection charges regardless of whether they trigger or not reinforcement
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. If DUoS moved towards more shallow connection, this would provide a stronger price signal to reduce usage of the network - because a more
"use of system" based charge is an avoidable cost, while by contrast a "connection" charge becomes an unavoidable sunk once it is paid and/or
committed to.
2. Zonal pricing provides sufficient granularity to provide an accurate price signal - Without introducing the problems of volatility and
unpredictability which would come from more nodal pricing.
3. Annuitized connection charge allows a user a good degree of certainty, albeit an annuitised shallow connection charge is likely to be
immaterial.
1. Size of, and method of deciding zones can result in volatile charges .
2. Shallow connection charges combined with zonal charging creates weak cost signals which may not be sufficiently strong to generate any
response
3. Strong time of use signals are appropriate only where the charging model is sufficiently predictable so users can predict with charges and make
decisions with clarity. This is of importance to new build generators (esp low carbon) where network charges can have sig. impact on project
viability.
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. Annuitisation and securitisation to connection ensures appropriate allocation of risk at point of connection
1. A shallower "use of system" based charge exposes users to the risk that after they have made their investment decision, the usage charge may
increase substantially due to changes in regulations, government policy, or the actions of other users - This is a particular issue for low/zero
marginal cost generators, or large industrial demand customers who after their investment decision have incurred substantial sunk cost of their
own assets and are therefore not able to respond to an increasing network use of system price signal. This is a risk they face out with of their
control.
2. With user commitment only extending to time of connection, risk tends to fall on wider body of users.
Despite requiring securitisation of annuity, creates risk of asset stranding related to reinforcement assets which disproportionately shields the
connectee from risk
3. Shallow connection charges socialises otherwise concentrated risk
4. Investment decisions have been made on the back of existing arrangements.
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. If DUoS moved towards shallow charging, then every year, users would face a price signal which reflected the incremental future network cost.
By contrast the current "shallowish" DUoS approach places more emphasis on providing a connection price signal at the point that users make
their initial investment decision.
2. Locational element of forward looking charge allow the price signal to be varied as the network and usage of the network changes.
1. Unpredictable behaviour by a user could trigger reinforcement costs which are never recovered from the user triggering them in full
2. Relatively weak price signals (shallow connection charges and zonal locational charges).
3. Lack of locational connection charge signal makes this charges unlikely to reflect costs. Requires strong zonal charge.
1 - Efficiently meet
the essential service
requirements of
network users
1. A move for DUoS from "paid up front" to "annuitised" may better meet requirements of users - A more level playing for access, as well as
lower cost to customers if the cost of capital of the DNOs is cheaper than the cost of capital of network users.
1. Uncertainty over path of future locational signals can present an investment risk.
2. Provides limited locational signal to connectees, and so does not provide cost signals to users to locate efficiently on the network
7 - Support efficient
network development
1. A DUoS move towards more shallow connection provides a new avoidable price signal fore users to reduce their use of the network - This can
result in more efficient use of the network, so reduce the need for the DNO to incur cost for network reinforcement
2. Incentive on network company to assess alternatives to traditional reinforcements as capacity limits reached.
3. Shallow connection charges can encourage trading or constraint management systems and development of DSO models where real time
signals of network constraints and flexibility can be delivered.
1. Less of an up-front signal/commitment from users to network companies around their enduring needs
2. Limited user commitment beyond connection risks asset stranding
3.Shallow connection charges enable customers to connect where they wish without being exposed to the costs driven on the network and
hence may drive unnecessary costs which the wider body of users will have to bear
4. Current charging regime does not incentivise the 'right' generation to come onto the grid at the 'right' location
8 - Be Practical
1. Shallow boundary and annuitisation allows all users to connect
2. Generally practical for large users.
3.Easy to administer (albeit transition could be challenging) with straightforward connection charging and reasonably simple zonal ongoing
charges
4. Shallow connections may be required for 'system flexibility
1. For DUoS, a more granular (zonal) locational charge may be more complicated to calculate - However, since TNUoS operates this way already, it
should be manageable.
2. User commitment arrangements become increasing difficult to administer as customer size deceases (multiple bilaterals?) and are probably
impractical at the small business/ domestic level. Significant issues in moving to this from anything other than a shallow connection boundary.
3. Transition would be challenging for distribution users who have already paid shallowish connection charges
9 - Be Proportionate
1. The benefits in terms of economic efficiency of price signals should outweigh the practical issues related to a more complicated tariff model.
2. Shallow boundary would mitigate the issue of relatively deeper connection boundary at distribution
3. Some granularity of locational signal may somewhat help mitigate increasing demand at distribution
4. Shallow connection charges are needed to fully use non network flexibility
1. Difficult to implement for smaller users
2. Not proportionate as minimal benefit delivered
C1-A: Existing transmission arrangements
Broadly similar to existing arrangement at Transmission level. Shallow connection boundary and locational signal allow user behaviour to be influenced as system costs change over time and better facilitates capacity trading/reallocation. Securitisation requirements can be a barrier for
smaller users.Assessment Criteria
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12.8 C1-B – shallowish connection charging with upfront capital payment
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. Upfront signal encourages locating demand where capacity exists.
2. Shallowish connection boundary results in capacity being initially allocated to users who value it
1. A move of TNUoS towards deeper ("shallowish") connection may introduce a greater need for secondary trading of connection rights, - which
may be less efficient.
2. Shallowish boundary at distribution is a barrier to investing in connections, potentially affecting optimal capacity allocation
3. Lack of locational signals
4. Moving to a deeper connection charge will have implications for behaviour in the Balancing Mechanism, for example how do parties with
physically firm access rights bid into the BM and how does this interact with TCLC
4 - Provide a level
playing field for all
network users
1. Lack of ongoing user commitment can help smaller players.
2. Consistent arrangements across T and D give immediate improvements by removing the discrepancy across the T/D boundary.
3. Shallowish connection charges ensure a connectee appropriately contributes to the cost of their connection, thus protecting the wider body of
users
1. Change of TNUoS from "shallow" to "shallowish" and "paid up front" could result in a previously unexpected call on cash reserves for network
users. Users with less strong balance sheets may be subject to a financial shock.
2. Obligation to pay up front creates barriers to some users
3. Questions about previous connectees who use up spare capacity - the connectee who drives reinforcement is liable for the apportioned
(shallowish) cost of reinforcement which may have been driven by a series of multiple connectees to that point
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. Connection charges will not be change over time based on other users actions on the network causing congestion
2. Shallowish connection charge provides some signal to users at time of connection
3. Lack of granularity assists with forecasting future charges
4. Strong up front connection charges enable users to make a very clear decision on the basis of the cost of connecting and the value of that
connection to the user
1. Existing Transmission users would face no ongoing locational price signal which they could respond to - The locational "use of system" price
signal would disappear and most users could not respond to the new deeper "connection" charge unless they were prepared to close their assets
before the charging arrangements changed.
2. Although connection charge is paid up-front, often difficult to estimate reinforcement required when making application
3. Lack of ongoing locational charges allows users limited scope to adjust behaviour on an ongoing basis as price signals are relatively weak
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. If TNUoS moved to "shallowish" with reduced "use of system" charges, this would reduce the uncontrollable risk to users of future tariff
increase - That their "use of system" charges may increase after they have incurrent their sunk cost investment decisions.
2. Opportunity to vary the risk allocation by varying the rules defining the shallowish boundary.
3. Ensures connectees are exposed to a proportion of the reinforcement costs they create, ensuring the wider body of users is shielded from the
risk of inefficient connections
1. Lack of user commitment
2. Lack of locational signals
3. Depend on precise rules of shallowish boundary - can result in risk mainly with wider body of users
4. Lack of location ongoing charges effectively socialises risk of ongoing reinforcements being required, rather than exposing users who have the
ability to influence the cost to more of the risk
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. Users face a charge broadly reflective of their expected impact on the network at the time of connection which reflects the investment that is
made to deliver their requirements
1. If TNUoS moved towards deeper connection charges and no locational charges, then existing transmission users would no longer face a price
signal which reflected future network costs.
2. Lack of locational signal in forward looking charges leaves reliance on temporal signals.
3. Lack of ongoing locational signal likely to under-value ongoing behavioural changes, where changes in behaviour post-connection may
influence future network costs
1 - Efficiently meet
the essential service
requirements of
network users
1. Customers have a more stable/known up-front charge to secure sufficient capacity for their needs rather than a potentially volatile ongoing
UoS charge
2. With more of the locational charge in the connection charge this can assist the investment case as there is a lower risk on locational charge
volatility.
3. Strikes a reasonable balance between enabling users to connect whilst not placing an undue cost burden on existing connectees
1. May be less efficient if a move to "paid up front" may result in higher cost to customers if network user cost of capital is greater than TO cost of
capital
2. Obligation to pay up front creates barriers to some users
3. Connection charges can become prohibitively high in constrained areas on the network and have a 'cliff edge' as constraint reached.
4. Lack of ongoing locational signal could result in inefficient use of the network and so unnecessary costs for users
7 - Support efficient
network development
1. Low requirement on Network companies to speculate on users' requirements
2. Can send a strong signal about capacity limits being reached and encourages users to connect where it is most efficient to do so for network
development
1. A move of TNUoS to no ongoing locational use of system price signals may result in less efficient locational investment decisions, so more
expensive network reinforcement - However, the disadvantage may be small since it is important to note that generator locational investment
decisions are driven primarily by other factors (not network charges) such as the availability of resource (wind, or hydro), policy decisions such as
subsidy for PV, or offshore wind, locations where it is possible to obtain planning consent (society prefers large power stations to be built away
from areas of demand such as towns and cities), availability of access to gas grid for fuelled stations and access to cooling, such as suitable coastal
sites.
2. Comparing costs of constraints and network investment may be more difficult where more network costs are recovered up front
3. Depends on the parameters in the shallowish boundary design, but can stall further network development in constrained areas due to high
connection charges.
8 - Be Practical
1. If TNUoS moved to be more like DUoS, then we already know that this approach is practical to operate
2. Arrangement exist and would be minimal change for the majority of users.
3. Easy to administer with simple ongoing charges
1. Obligation to pay up front creates barriers to some users
2. Shallowish boundary creates barriers to some users
3. Integrating flexibility and compensated connect and manage regimes difficult due to shallowish connection boundary.
4. Would require a more complex connection charging methodology at transmission, and transition could be challenging with the potential for a
'cliff-edge' before which customers could connect more cheaply
9 - Be Proportionate
1. Least change for most users
2. Benefits clear, albeit with improvements which could be made
1. For TNUoS to change to be more like DUoS may be disproportionate, because it would cause some disruption, but fail to solve the key issues
the change is expected to address
2. Lack of ongoing locational signals cannot help support a more active distribution network with flexibility
3. Upfront payment of connection charges on a shallowish boundary is a material issue as identified by Baringa
Assessment Criteria
C1-B: Existing distribution arrangements
Broadly similar to existing arrangement at Distribution level. There is some granularity of locational charges due to there being 14 DNOs but this is not caused by design of the charging framework. A minority of customers (EHV) do have locational charges. Less volatility in locational charges
but no forward looking locational signal to influence behaviour. More difficult to facilitate capacity trading/reallocation.
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12.9 C1-C – deep connection charging with upfront capital payment
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. Strong upfront locational signal means that entire cost of locational decision rests with connectee.
2. Deep connection charging results in capacity being initially allocated only to those who value it very highly
1. A move to ("deep") connection may introduce a greater need for secondary trading of connection rights, - Which may be less efficient than
price signals provided by "use of system" charges. Secondary trading clearing prices would reflect the value to the users instead of reflecting the
cost to the DNO.
2. Deep boundary paid upfront will be a significant barrier to some users, affecting optimal capacity allocation and may lead users to exit grid
3. Strong up front signal in isolation makes any reallocation of capacity very difficult and encourages hoarding.
4. Lack of locational ongoing charges could result in the value of ongoing usage of capacity being hidden from users, and so result in inefficient
allocation
5. May result in capacity 'hoarding' due to sunk cost. This could be removed should there be a penalty e.g. combined with use it or lose it
6. Interferes with behaviour in the BM, as parties may need to bid above marginal costs to ensure cost of network connection recovered.
4 - Provide a level
playing field for all
network users
1. Deep connection charges ensure a connectee contributes fully to the cost of their connection, thus protecting the wider body of users
2. Ensures connectee fully contributes to the cost that they impose on the system
1. A move to "deep" connection charging with "paid up front" would provide a competitive advantage to users with stronger balance sheets and
therefore disadvantage smaller users and community groups.
2. Questions about previous connectees who use up spare capacity - the connectee who drives reinforcement is liable for the full apportioned
cost of reinforcement which may have been driven by a series of multiple connectees to that point
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. Connection charges will not change over time based on other users actions on the network causing congestion
2. Lack of granularity in wider ongoing charges assists with forecasting future charges
3. Strong up front connection charges enable users to make a very clear decision on the basis of the cost of connecting and the value of that
connection to the user
4. Users able to make predictable investment decision based on certain connection charge
1. No forward price signal to encourage action (locational or otherwise).
2. There is potential that connection costs could change between winning a CM agreement and connecting leading to inefficient bids in subsidy
scheme raising costs for all network users.
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. True reflection of wider network cost is funded by the individual user, wider users are not at risk of funding stranded assets due to significant
change in behaviour of the single user
2. Protects existing connectees from all risk related to new customers once they are connected
3. Unlikely to get 'stranded assets' as there will be a lower SRMC. (downside of this is less plant will connect)
1. Individual customer bears full network cost regardless of future changes in usage, network companies are in a position to dynamically allocate
capacity and therefore reduce overall risk
2. Deep connection places excessive risk for reinforcement on individual users
3. No ability to allocate risk to the wider body of users.
4. Exposes the wider body of users to risks associated with failed schemes if not funded upfront.
5. High levels of risk on connectee
6. Increases cost of the Capacity Market by raising costs of parties bids, effectively reallocating the risk back to all consumers
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. Users face a charge fully reflective of their expected impact on the network at the time of connection which reflects the investment that is
made to deliver their stated requirements
2. Strong cost reflective price signal at time of connection.
1. Connection charge based on forecast future network reinforcement is subjective because it is based on the DNO/SO making assumptions
about the future which may turn out to be wrong
2. Users may be charged for future network reinforcement which may never actually happen
3. It is not possible to objectively, or accurately attribute specific deep network reinforcement to individual users because network
reinforcement is lumpy and partly based on anticipatory investment regarding future users.
4. Connection charges tend not to reflect "benefits" which users cause from avoided reinforcement and no incentive for sharing/trading
5. Lack of ongoing locational signal likely to under-value ongoing behavioural changes, where changes in behaviour post-connection may
influence future network costs
1 - Efficiently meet
the essential service
requirements of
network users
1. Can provide certainty on network costs to assist investment case as there is a low risk on locational charge volatility.
2. Avoids connected customers contributing to the costs of new connections
1. No change in charge if users' core needs change over time
2. Deep boundary paid upfront will be a significant barrier to some users, affecting optimal capacity allocation and may lead users to exit grid
3. Connection costs become high (and have a 'cliff edge' as constraint reached) in constrained areas preventing the development of users
projects.
7 - Support efficient
network development
1. Incentive on users to flex usage and location to avoid upfront costs. Strong upfront locational signal minimises risk of stranded asset costs (if
costs recovered up front).
2. Strong connection price signal encourages users to connected where it is most efficient for network development
3. Incentive for users to 'flex' usage and location
1. A change to no ongoing locational price signals may result in users making less economically efficient investment decisions, which may result
in a greater need and cost of network investment
2. Deep boundary paid upfront will be a significant barrier to some users, affecting optimal capacity allocation and may lead users to exit grid
3. Strong upfront locational signal becomes so strong in constrained areas that further network development stalls.
4. Lack of ongoing location signal leaves the network operator no means of giving ongoing signals for better use of the network.
5. Technology which can reduce constraints has less incentive to connect (i.e. storage) if up front connection costs are higher and use of system
charges are lower
8 - Be Practical
1. Simple to implement
2. Easy to administer with straightforward connection charging and simple non-locational ongoing charges
3. Easy to adopt however difficult for transition
1. Transition will be challenging - to move existing users with shallow connection charges to deep connection charges.
2. Deep boundary paid upfront will be a significant barrier to some users, affecting optimal capacity allocation and may lead users to exit grid
3. Difficult to see how to implement in a network using flexibility products.
4. Transition likely to be challenging with the potential for a 'cliff-edge' before which customers could connect more cheaply
5. Will require to changes to CM, wholesale and ancillary services markets.
9 - Be Proportionate
1. Works best for users with large portfolios of projects (can choose which project to invest in to find cheaper connections).
2. Numerous benefits to connected customers who are protected from the costs driven by new connectees
1. Disproportionate, because it would cause significant disruption and may fail to solve the key issues.
2. Deep boundary paid upfront will be a significant barrier to some users, affecting optimal capacity allocation and may lead users to exit grid
3. Size of connection charges on constrained networks is unlikely to be proportionate
4. Disproportionate barrier to connection
Assessment Criteria
C1-C: Strong connection charging
Similar to the arrangement that existed at distribution level for DG connections prior to 2005. Whilst it gives a strong initial locational signal, up front costs can be so high that no connections take place. There is no incentive to release capacity that is not needed nor any ability to allocate risk
between connectee and wider body of users.
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12.10 C1-D – shallow connection charging with focus on strong ongoing usage signals
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. Strong locational signal
2. Shallow connection boundary is efficient for capacity allocation if users face cost reflective ongoing use of system charges instead
3. Efficient for capacity allocation the flexibility of charging (e.g. no sunk cost)
1. Weaker upfront signal from users of their needs which could make planning more difficult. Networks are left to react to user behaviour.
2. Lack of user commitment and shallow boundary may encourage speculative applications.
4 - Provide a level
playing field for all
network users
1. Shallow would mean users face the same ongoing "use of system" price signals
2. Shallow boundary with annuitisation allows all users to connect
3. Lack of large upfront connection costs can help smaller players.
4. Risk of cross-subsidy with shallow connection charges is avoided through highly locational ongoing charges
1. Stronger locational signals could lead to users with similar usage being charged very differently based on their location which they have little
control over
2. For large demand users volatility of network tariffs may place proportionately higher costs on users for whom energy is not core business
3. Nodal type changes can be volatile and hard to forecast.
4. Modelling is challenging - if based on time to reinforce and a new connectee drives reinforcement, time to reinforcement will be low and so
ongoing charges low creating a cross-subsidy
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. If truly cost reflective, this will provide the best possible signal to users allowing them to take the action that best reduces their impact on the
network.
2. Connection charges more predictable and locational signals can reflect changing capacity available.
3. Annuitised connection charge allows a user a good degree of certainty, albeit an annuitised shallow connection charge is likely to be
immaterial.
4. Nodal charges likely to give strong cost signal on an ongoing basis
1. Volatile (potentially very volatile) nodal prices are difficult for users to predict, so very difficult for users to take them into account when
making investment decisions
2. Price volatility inevitably puts higher prices to end customers
3. Granularity of charges makes charges less predictable (different to volatile).
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. Annuitisation and securitisation to connection ensures appropriate allocation of risk at point of connection
2. Securitisation until connected protects the wider customer base from risks before connection
1. Nodal pricing is volatile, so puts more risk onto users - This is not appropriate since users can not control the factors causing the volatility and
users will generally not be able to make investment decisions in response to those volatile prices - so users would be exposed to greater risk
with no associated system benefit.
2. Network companies/wider users bear risk of significant changes in user behaviour that trigger investment, if the use is not sustained wider
customers will bear this cost
3. Lack of user commitment
4. Risk strongly allocated to wider body of users due to shallow boundary and lack of user commitment.
5. Despite requiring securitisation of annuity, creates risk of asset stranding related to reinforcement assets which disproportionately shields the
connectee from risk, albeit over time the connectee would expect to contribute to that reinforcement through ongoing locational charges
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. Users would face an ongoing price signal which reflected the incremental future network cost or benefit which they caused.
2. Strong locational signal
3. Users would face an ongoing price signal which reflected the incremental future network cost or benefit which they caused.
4. Ongoing locational charges should be highly cost reflective, with incremental future costs and benefits reflected on an ongoing basis if it can
be calculated accurately (modelling burden)
1. If a user has infrequent but high peak usage, this could trigger significant reinforcement which is not recovered through usage charges due to
infrequent high usage
2. Lack of connection costs signal.
3. Connection charge does not reflect costs or benefits locationally
1 - Efficiently meet
the essential service
requirements of
network users
1. Shallow boundary and annuitisation allows all users to connect
2. Shallow charges and lack of user commitment reduce upfront development costs to users
3. Meets the requirements of connecting customers by enabling them to connect at low up front cost and with confidence of long term costs.
4. Provides ongoing locational signal to connectees, and so provides cost signals to users to both locate and then use (e.g. temporally) the
network efficiently
5. If time of use signals are efficient and predictable users can modify consumption patterns or invest with more certainty
1. Potentially volatile based on surrounding users' behaviours, therefore cost for essential requirements may change unpredictably
2. Uncertainty over path of future locational signals can present a significant investment risk with nodal charging.
7 - Support efficient
network development
1. A DUoS move towards more shallow connection provides a price signal to reduce network usage - This can result in more efficient use of the
network, so reduce the need for the DNO to incur cost for network reinforcement. TNUoS is already shallow.
2. Incentive on network company to assess alternatives to traditional reinforcements as capacity limits reached.
3. Ongoing cost signals enable users to take action to use the network efficiently and so enable the network operator to develop efficiently
4. Low connection cost (albeit may not be in the right location)
5. Supports development of flexible generation, storage and demand which can respond to clear ToU signals
1. Nodal pricing may result in less efficient user investment decisions, which in turn causes less efficient network investment - If the additional
tariff volatility caused by moving from zonal to nodal results in a reduced ability for users to take the price signal into account when making
investment decisions.
2. Lack of user commitment
3. Risk that highly locational signals are so volatile that they are ignored by customers. Lack of user commitment can result is speculative
applications that risk stranded asset development.
4. Shallow connection charges enable customers to connect where they wish without being exposed to the costs driven on the network within
the connection charge and hence may drive unnecessary costs which the wider body of users will have to bear
8 - Be Practical
1. Shallow boundary and annuitisation allows all users to connect
2. Fits well with using non-network solutions to expand capacity.
3. Connection charge simple and easy to administer. It is possible to manage volatile charges if they are predictable
4. No required interaction with the Capacity Market
1. Nodal tariffs may be more difficult to publish and more difficult for users to understand.
2. Calculating/modelling more cost reflective charges for all users would be a huge exercise, especially if in near-real-time
3. Lack of user commitment
4. Volatility in pricing will be difficult for some users to manage
5. Strong locational signal may be practically difficult
6.Transition arrangements challenging for distribution
9 - Be Proportionate
1. Shallow boundary would mitigate the issue of relatively deeper connection boundary at distribution
2. Strong locational signal may somewhat help mitigate increasing demand at distribution
3. Shallow connection charges are needed to fully use non network flexibility
4. Simple connection charge easy to administer
1. Move to nodal prices instead of zonal would introduce additional complexity and additional risk while the impact on the cost to the system
may be zero, or detrimental.
2. Lack of user commitment may not help resolve increasing use of lower voltages
3. Difficult to implement for smaller users
Assessment Criteria
C1-D: Strong usage charging
‘Nodal’ type locational signal due to either difficulty of defining zones or this being impractical due to the multi voltage layers at distribution level. Annual payment to recover connection charge but no securitisation of wider works. Provides forward looking price signals but highly granular
locational signals can be volatile and hard to predict and lack of user commitment can lead to speculative applications reducing the efficiency of capacity allocation.
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Appendix Five– Advantages and disadvantages of C2 Combinations as Expressed by Task Force members
12.11 C2-A – temporal signals
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. Strong TOU and locational signals
2. Harmonised price signals would improve price reflectivity of distribution and transmission connected assets in the BM
1. Difficult for DNO/SO to predict how users will respond to dynamic TOU price signals, which makes this a blunt and ineffective tool for the short-
term operational reallocation of capacity for managing network constraints.
2. Assuming BM remains in place for transmission system, then DUoS TOU price signals would need to be fully cost reflective and dynamic at high
resolution.
3. Failure to achieve this would fail to optimise short-term capacity allocation because they would provide detrimental conflicting operational
price signals compared with the BM.
4 - Provide a level
playing field for all
network users
1. Static TOU tariffs are easier to understand for all users
2. (Large demand users) Absence of requirement to participate in complex mechanisms such as the BM avoid placing proportionately higher costs
on users for whom energy is not core business
1. If TOU price signals fail to be fully cost reflective, then they would provide an unfair competitive advantage to users who are better able to
take action to avoid them.
2. (Large demand users) Volatility of network tariffs may place proportionately higher costs on users for whom energy is not core business
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. The time at which customers use their energy is an important factor in their impact on the network (networks are built to meet requirements
of peak demand which is highly temporal), therefore reactions to temporal signals will have a meaningful impact on the network
2. Strong locational and TOU signal
3. Provides a level playing field for whole system costs - users pay during periods of constraints
4. Transparent and predictable signals provides clear signals to dispatch. Ideally avoiding dynamic UoS charges.
1. For TOU price signals to be fully cost reflective, then they need to be dynamic at high resolution. This would make it very difficult for users to
predict when planning their dispatch.
2. Static TOU price signals would provide price signals users could better respond to, but these would fail to be effective for short-term operation
of constraint management.
3. Likely very volatile signal
4. Volatile prices will inevitably increase cost to consumer
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. Increasing volatility and predictability of tariffs provides a clear signals for users to modify consumption or invest in new assets to avoid higher
charges
1. Volatile cost reflective dynamic TOU price signals would expose users to increased risk of network and operational conditions outside of users'
control and which they will find it difficult to respond to, so there is little/no system benefit to exposing users to those risks.
2. Exposes DNO/SO to the risk that users may over/under respond to TOU price signals
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. Dynamic TOU price signals updated in real time at high resolution may provide a cost reflective price signal for operational dispatch only.
2. TOU price signals may be effective for reflecting future network cost if used as a proxy for user operational characteristics (such as reflecting
the type of profile of a particular demand customer), rather than providing an explicit TOU price signal which users are expected to respond to.
3. Static ToU signals can be predictable and reflective if calculated ex ante and charged ex post. allowing users to reliably forecast their charges
and modify behaviour in response.
1. Static TOU price signals set in advance would fail to provide cost reflective operational price signals.
2. TOU price signals are an ineffective approach for reflecting "future network cost" for incentivising user investment decisions. Static TOU are
not cost reflective, while dynamic TOU are too unpredictable to inform user investment decisions.
3. Lack of ability to re-allocate capacity
4. Dynamic ToU signals are not predictable and make it difficult to influence user behaviour
1 - Efficiently meet
the essential service
requirements of
network users
1. (Large demand users) Absence of requirement to participate in complex mechanisms such as the BM avoid placing proportionately higher costs
on users for whom energy is not core business1. (Large demand users) Volatility of network tariffs may place proportionately higher costs on users for whom energy is not core business
7 - Support efficient
network development
1. Incentive on users to flex usage and therefore collectively make better use of existing capacity
2. Predictable UoS charges encourage development in flexible capacity such as storage which can defer network investment
1. If TOU price signals are ineffective at providing cost reflective price signals which users can respond to with investment decisions, then they
would fail to support efficient network development.
2. Lack of ability to re-allocate capacity.
3. Volatile and complex tariffs limit the influence on user behaviour and so could lead to excessive reinforcement
8 - Be Practical
1. (Large demand users) Absence of requirement to participate in complex mechanisms such as the BM avoid placing proportionately higher costs
on users for whom energy is not core business
2. Minimal change required to CM arrangements
1. Dynamic TOU price signals updated in real time would require substantial resource, which may not be practical.
2. Lack of trading.
3. Very volatile pricing.
4. Likely very difficult to administer
9 - Be Proportionate
1. Strong locational and TOU signal may somewhat help mitigate increasing demand at distribution
2. Fair for whole system costs. E.g. you pay for the system when you are using it1. The complexity of real time dynamic TOU price signals would not be proportionate given the increased risk and low benefits it would deliver.
Assessment Criteria
C2-A - Temporal Signals
There are strong tariffs that have a high degree of locational and temporal granularity. There are no options for reallocation of capacity rights in this option.
For example: tariffs could be nodal and change every 30mins
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12.12 C2-B – extended balancing mechanism
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. Ability to trade in the short-term - realise the true value
2. Aggregator market is large and competitive, there would be plenty of scope for participants to provide BM aggregation services1. (Large demand users) Participation in BM may prove complex and effectively remove significant capacity from the market
4 - Provide a level
playing field for all
network users
1. Transition to Smart Flexible System should open the door to users of all types and sizes participating in the BM for services to the SO for
operating the transmission system. Since users will be bidding in to the BM anyway, it should be relatively practical to extend the BM to include
DSO action for managing the Distribution system.
1. This may disadvantage customers who do not have the knowledge/resources to take part in the mechanism
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. The BM is effective at providing operational price signals to those users who can respond to them, while avoiding imposing operational risk
and price signals on those users who can't respond to them.
2.Provision of a market mechanism for constraint improves situation at distribution
3. BM takes into account locational signals and can optimise consumption/generation around constraints
1. Relatively high engagement needed from users wishing to react, this could limit participation and therefore actions taken.
2. (Large demand users) Participation in BM may prove complex to the point where users cannot respond to the signal created.
3. Lack of temporal signals
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. As long as network charges provide a cost reflective locational price signal for investment, then the BM approach of ensuring users are "made
whole" is appropriate. The operational risk of operating the system then falls on the SO, which is best placed to manage it.
2. Provision of a market mechanism for constraint improves situation at distribution
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. BM constraint costs are used to provide a clear and effective network investment signal using Cost Benefit Analysis in meeting the Economy
Criteria of the Transmission investment standards SQSS. This network investment cost is then reflected through the TNUoS Year Round tariff
element. It would be possible to use a similar approach for DUoS.
2. Provision of a market mechanism for constraint improves situation at distribution
3. Costs of constraints within network can be allocated to create area specific DBSUoS or imbalance prices creating a signal to parties to buy
energy behind constraints
1. (Large demand users) Participation in BM may prove complex to the point where users cannot respond to the signal created.
2. Lack of locational/TOU signals.
1 - Efficiently meet
the essential service
requirements of
network users
1. In this model, network users place bids in the BM to reflect the value to that user of their short-term access to the network. In this way users
who place a high value on access get to keep it, while users prepared to give up their access are compensated and "made whole".
2. Complimentary to locational ToU signals as parties can bid into the mechanism with knowledge of their own costs
1. (Large demand users) Participation in BM may prove complex to the point where users cannot respond to the signal created.
2. Lack of locational/TOU signals
7 - Support efficient
network development
1. BM model provides price discovery and clear economic evidence to evaluate whether it is/is not economically efficient to make particular
network reinforcement investments.
2. Provision of a market mechanism for constraint improves situation at distribution
3. short-term trading and reallocation can support investment in storage to take advantage of locational pricing signals
1. (Large demand users) Participation in BM may prove complex to the point where users cannot respond to the signal created.
2. Lack of locational/TOU signals
8 - Be Practical
1. The Balancing Mechanism already operates for existing users which are a Balancing Mechanism Unit (BMU). It is therefore a proven approach
which could be extended to other smaller users.
2. Not too complex to create large integrated system as a EU level scheme is also being developed
3. Competition from aggregators will provide multiple routes to market
4. Minimal changes to CM
1. BM requires a not-insignificant level of engagement from users beyond simply changing their behaviour, this may not be practical for smaller
customers.
2. (Large demand users) Participation in BM may prove complex to the point where users cannot respond to the signal created
3. Could require licence changes to exemptions so parties must be in BM
9 - Be Proportionate
1. Balancing Mechanism approach provides substantial benefits with limited additional complexity.
2. Provision of a market mechanism for constraint improves situation at distribution
3. Minimal changes to CM
1. Lack of locational and TOU signals exacerbate changing use at distribution
Assessment Criteria
C2-B - Balancing Mechanism
Access can be sold and bought in the short term between users and networks. This could be through a type of extended balancing mechanism across both transmission and distribution. There are no locational and temporal signals in this option.
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12.13 C2-C – full range of operational signals
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. Ability to trade in the short-term and medium-term both in a market and bilaterally
2. Some locational and TOU signals
3. Suppliers and aggregators can use portfolios to provide aggregate capacity to So across range of timescales
1. Different approaches on different networks - If TOU tariffs fail to be cost reflective, then TOU tariffs on one network (e.g. Distribution) can
distort BM dispatch for managing other networks (other Distribution networks and Transmission network)
2. Different approaches on same network - Dynamic TOU would create a problem even if TOU tariffs are cost reflective because there will be two
different price signals for the same purpose of allocating short-term capacity on an operational basis. Feedback effects could lead to unintended
consequences, unpredictable and volatile prices which would be economically inefficient and result in higher cost to customers.
3. Volatile and complex signals limit the influence on user behaviour and so could lead to excessive reinforcement
4 - Provide a level
playing field for all
network users
1. (Large demand users) Weak locational and TOU signals may support access for all
2. Effective price signals across timescales encourages aggregation and competition in supply - allowing economies of scale
1. If TOU signals fail to be fully cost reflective for BM participants, then this would distort competition in the BM
2. Volatile and complex signals limit the influence on user behaviour and so could lead to excessive reinforcement
3. (Large demand users) Participation in BM may prove complex and effectively remove significant capacity from the market
4. Bilateral trading may favour larger parties
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. This will provide the best signal to users of their impact on the network meaning any reaction will be meaningful to network investment
impacts
2. BM allows parties to reflect their own costs to SO, which includes ToU and other network charges, therefore better dispatch is achieved when
parties set their own costs.
1. If BM and TOU are providing different, contradictory price signals for the same users for the operation of the same network, then this would
not provide effective price signals which users could respond to.
2. Bilateral trading enables some users to arbitrage between other price signals which may lead to economically inefficient behaviour in BM and
TOU responses via adverse selection
3. (Large demand users) Participation in BM may prove complex
4. Complexity may hinder most optimal market solution
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. Some locational and TOU signal
2. Provision of a market mechanism for constraint improves situation at distribution
3. Ability to trade allows change of use
4. Ability to aggregate customer and generation together could offset risk through portfolio approach, vertical integration and economies of scale
1. DNO/SO trying to use BM tools to manage operational dispatch may be hampered if users are also self dispatching for TOU price signals.
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. Location and time of usage impact investment, therefore sending these signals to users is truly cost reflective
2. Provision of a market mechanism for constraint improves situation at distribution
3. Ability to trade allows change of use
1. If both TOU and BM price signals are provided to the same users for action to manage the same network, then the net effect would not be cost
reflective.
2. There may be a risk that if some types of users are exposed to TOU tariffs, while different types of user are exposed to BM instead, then users
which cause the came cost/benefit may face different prices.
1 - Efficiently meet
the essential service
requirements of
network users
1. The ability to hedge network access through medium to short-term products allows users to effectively manage the risk of the costs of network
access and buy the access they require
2. The ability to buy extra access through short-term reallocation or signalling pricing in the BM allows parties to get the access they want
1. Potentially volatile based on surrounding users' behaviours, therefore cost for essential requirements may change unpredictably
2. Volatile and complex signals limit the influence on user behaviour
3. (Large demand users) Participation in BM may prove complex
7 - Support efficient
network development
1. Should support type of development at correct location (assuming that these parameters are captured)
2. Incentive on users to flex usage and therefore collectively make better use of existing capacity
3. Provision of a market mechanism for constraint improves situation at distribution
4. BM model provides price discovery and clear economic evidence to evaluate whether it is/is not economically efficient to make particular
network reinforcement investments.
5. Ability to trade allows change of use
1. If there is a conflict between the price signals provided by TOU and BM, then this will fail to provide an efficient price signal for network
businesses to invest in network reinforcement or could lead to excessive reinforcement
2. (Large demand users) Participation in BM may prove complex and effectively remove significant capacity from the market
3. Bilateral trading may favour larger parties, reducing capacity trading overall
8 - Be Practical
1. It may be practical to use different approaches (TOU Vs BM) for different types of user (e.g. demand Vs generation) or for the management of
different networks (T Vs D). There may be reasons why a different approach may be more suitable in different circumstances. However, it is not
practical to use both for the same users for management of the same network.
1. Calculating/modelling more cost reflective charges for all users would be a huge exercise, especially if in near-real-time
2. Could require licence changes to exemptions so parties must be in BM
9 - Be Proportionate
1. If there is a sound economic justification then it may be proportionate to use different approaches (TOU and BM) for different types of user, or
for different networks.
2. Provision of a market mechanism for constraint improves situation at distribution
3. Some locational and TOU signal may somewhat help mitigate increasing demand at distribution
4. Cost reflective approach
Assessment Criteria
C2-C - Full Range of Operational Signals
There are a range of signals designed to influence user behaviour.:
- A form of extended balancing mechanism across T&D for ST trading of access rights between users and networks
- Users can trade M-LT access rights with other users
-There are tariffs that vary temporally and locational. They are not very strong and may be set by zones for 3 hour periods for example.
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12.14 C2-D – bilateral trading
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. Users trading bilaterally could potentially ensure efficient allocation of existing capacity, particularly where users are willing to change
behaviour to "release" existing capacity once it is given value.
1. Bilateral trading involves a smaller, less liquid market, which could be expected to result in a less economically efficient result. May favour
larger parties, reducing capacity trading overall
2. DNO/SO would have poor control of the short-term operational dispatch of particular users, which would make it difficult for DNO/SO to
optimise capacity allocation on an operational timeframe.
3. Lack of locational and TOU signals
4 - Provide a level
playing field for all
network users
1. By making requirements for capacity allocation on suppliers you could encourage supply market competition , lowering costs for consumers
trading access.
1. Users with better contacts and resources would have a competitive advantage and risk speculative trading behaviour
2. Bilateral trading may favour larger parties, reducing capacity trading overall
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. Parties will have sufficient view of their own costs once capacity has been secured to make decisions about operation
2. Mandatory and transparent platforms for trade notifications and reserve prices can provide price transparency
1. Bilateral traded prices are more likely to be opaque, not publically available and very difficult to predict since they are based on a negotiated
agreement based on the value to the respective parties and their relative bargaining strengths.
2. Lack of locational and TOU signals
3. Lack of market for short-term and long-term constraint
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. For deep connection boundary risk may be reduced for users who would otherwise be committed to paying deep connection charges. By
contrast, for shallow connection, bilateral trading is not generally needed, as shown by TNUoS where it is an option which is rarely used.
2. Ability to aggregate customer and generation together could offset risk through portfolio approach, vertical integration and economies of scale
1. Lack of locational and TOU signals
2. Lack of market for short-term and long-term constraint
3. As suppliers forecast increasing use in a network, they will need to buy more access rights, and therefore be willing to pay more. This creates a
price signal for generation or network development in those zones who can sell that capacity.
Co
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efle
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3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. Ability to trade bilaterally
1. Price signals do not reflect investment cost, but they reflect the value to the respective users in the trade. A key question is what provides the
anchor value for the access right being traded? - In TNUoS, this is the value of TEC. In DUoS, this is the value to the respective users of being
constrained off without receiving compensation i.e. trading their place in the last in / first out order of curtailment.
2. Lack of locational and TOU signals
3. Lack of market for short-term and long-term constraint
1 - Efficiently meet
the essential service
requirements of
network users
1. Firm access available for core capacity 1. Bilateral trading is better than nothing, but it is less liquid and transparent, so less effective at delivering the requirements of users than a BM.
7 - Support efficient
network development
1. Would reveal the true value of capacity to users (to some extent, market stronger for this) allowing networks to make informed decisions on
whether investment is in best interest of customers on a holistic basis
2. Needs to be a market platform for trades to be notified to, no reason network operators would be unable to see this with prices included
1. Difficult for network businesses to obtain a price signal for network investment from bilateral trades between users.
2. Lack of locational and TOU signals
3. Lack of market for short-term and long-term constraint
8 - Be Practical
1. Exchange rates are needed when trading access between different types of user. It would be impractical for DNO/SO to calculate these for
different types of user for different locations in real time, if there was a high volume of bilateral trading.
2. Lack of network-user signals beyond firm access
3. Requires changes to CM arrangements
9 - Be Proportionate
1. It would appear disproportionate to dismantle existing well functioning arrangements in the BM to replace it with bilateral trading, especially
if bilateral trading were a less effective solution.
2. Lack of locational and TOU signals exacerbate changing use at distribution
Assessment Criteria
C2-D - Bilateral Trading
Users are able to trade their access rights in the ST< with other users. Trades are bilateral between parties. This allows unused or less valued capacity to be used by other parties. There are no locational or temporal tariffs with this option.
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12.15 C2-E – market trading
Advantages Disadvantages
2 - Optimise Capacity
Allocation
1. More liquid than bilateral trading
2. Ability to trade in the medium-term
1. DNO/SO would have poor control of the short-term operational dispatch of particular users, which would make it difficult for DNO/SO to
optimise capacity allocation on an operational timeframe.
2. No ability to trade in the short-term
3. Lack of locational and TOU signals
4 - Provide a level
playing field for all
network users
1. (Large demand users) Absence of requirement to participate in complex mechanisms such as the BM avoid placing proportionately higher costs
on users for whom energy is not core business
2. By making requirements for capacity allocation on suppliers you could encourage supply market competition , lowering costs for consumers
trading access
1. Risk of speculative behaviour putting some users at a competitive disadvantage
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
1. Unlike bilateral trading, market trading would publicly reveal the value being revealed by users allowing a wider audience to participate and
therefore react
2. Ability to trade in the medium-term
3. Parties will have sufficient view of their own costs once capacity has been secured to make decisions about operation
1. Lack of locational and TOU signals
2. Lack of market for short-term constraint
3. Difficult to anticipate what the market clearing price may be when planning dispatch.
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
1. Ability to aggregate customer and generation together could offset risk through portfolio approach, vertical integration and economies of scale1. Lack of locational and TOU signals
2. Lack of market for short-term constraint
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
1. Ability to trade in the medium-term
2. As suppliers forecast increasing use in a network, they will need to buy more access rights, and therefore be willing to pay more. This creates a
price signal for generation or network development in those zones who can sell that capacity.
1. If locational charges are calculated differently for different types of user, then secondary trading may enable users to arbitrage different
charging formulas in a way which results in the full year charge they pay not being cost reflective of the cost they cause.
2. Lack of locational and TOU signals
3. Lack of market for short-term constraint
1 - Efficiently meet
the essential service
requirements of
network users
1. Firm access available for core capacity
7 - Support efficient
network development
1. Would reveal the true value of capacity to users allowing networks to make informed decisions on whether investment is in best interest of
customers on a holistic basis
2. Ability to trade in the medium-term
1. If secondary trading enables some users to arbitrage different charges at different times, then net price signal received by users may be
different from what the DNO/SO intended when the tariffs were originally calculated.
2. Lack of locational and TOU signals
3. Lack of market for short-term constraint
8 - Be Practical1. Little attempt to provide locational, TOU or operational short-term signals is relatively simple
1. Must be facilitated centrally
2. Lack of operational network-user signals
3. requires change to CM arrangements
9 - Be Proportionate1. Lack of locational and TOU signals exacerbate changing use at distribution
Assessment Criteria
C2-E - Market Trading
Users are able to trade their access rights in the ST< with other users. Trades are made within open markets. This allows unused or less valued capacity to be used by other parties. There are no locational or temporal tariffs with this option.
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Appendix Six– Advantages and disadvantages of Tariff Design Options as Expressed by Task Force members
12.16 Fixed charges
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Depends on extent to which costs are driven per-head
- Depends on ability to limit volatility
- Does not incentive the right behaviour and low usage customers pay for high usage.
- Risk of [inefficient] user disconnection
- Limited cost-reflectivity so not appropriate for a FLC
4 - Provide a level
playing field for all
network users
- Simple
- Depends on extent to which costs are driven per-head
- Depends on ability to limit volatility
- Limited cost-reflectivity so will not create a level playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Fixed charges are completely predictable for the end user
- A user cannot take action (other than disconnection) to avoid fixed charges, so arguably does not meet the 'to allow them to take action'
element
- Question if these are predictable year on year
- Very predictable charge but not effective as not cost-reflective
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Charges not affect by usage, so parties can't avoid them, recovering costs over wider base
- Depends on extent to which costs are driven per-head
- Depends on ability to limit volatility
- No competition
- Could encourage consumers to disconnect, reducing charging base
- Lack of cost-reflectivity means inappropriate risk allocation
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- May be used to give a forward looking cost signal for costs which will be avoided if the user disconnects
- May be appropriate for particular groups who's response would not improved if the cost was more locationally cost reflective, or if the fixed
charge reflects a particular element of cost which is the same for a given type of user or a given location
- May be appropriate for local assets, where (assuming the asset is suitably sized) the cost to the network operator is stable over the life of the
asset
- Risk of over-valuing 'off-grid' or behind the meter solutions if fixed charges are too high.
- A generalised fixed charge is less likely to be cost reflective.
- Not cost-reflective for FLC UoS charges
1 - Efficiently meet
the essential service
requirements of
network users
- Vulnerable users know the cost - Vulnerable users may be overcharged
7 - Support efficient
network development
8 - Be Practical - Easily applied to all users - Does not contain incentive
9 - Be Proportionate - Simple to implement
Assessment Criteria
Tariff Elements - Fixed Charges
Charges which are applied on a per user basis as long as the user remains connected
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12.17 Unit rates
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Depends on extent to which costs are driven per-kWh
' Depends on ability to limit volatility
- Potentially able to be used to provide an appropriate FLC
4 - Provide a level
playing field for all
network users
- Depends on extent to which costs are driven per-kWh
- Depends on ability to limit volatility
- Could provide a level playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- A unit rate is relatively easy for some users to avoid by taking action.
- A time bounded unit rate could signal the contribution to peak demand across a diverse network, and averaging over a period of time (such as
the Annual Load Factor in transmission) would avoid conflicts between investment and dispatch signals.
- Predictable charge
- If the unit rate is designed to incentivise investment decisions, then it may incentivise inefficient dispatch behaviour.
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- More cost-reflective and hence better at allocating risk
- Depends on extent to which costs are driven per-kWh
- Depends on ability to limit volatility
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- A unit rate is relatively easy for some users to avoid by taking action - to the extent that this results in lower network costs, this is cost-
reflective.
- Potentially cost-reflective for some elements of the charge
- Risk of over-valuing reduced usage if not targeted locationally or temporally
1 - Efficiently meet
the essential service
requirements of
network users
- At LV reflects cumulative contribution to network reinforcement requirement, protecting disproportionate allocation of costs to an individual
user.
7 - Support efficient
network development
- Right price signal for right behaviour if time of use
- Depends on the extent users can respond and appropriate flexibility can be purchased
8 - Be Practical
- Unrestricted unit rates easily applied to all users
- Time bounded units rates easily applied to HH metered users
- Sends a price signal
- Time bounded unit rates cannot be accurately applied to NHH metered users as network company has no visibility of the time of use
9 - Be Proportionate
Assessment Criteria
Tariff Elements - Unit Rates
Standard unit charges, applicable to energy usage with a number of sub-options for unit rates which vary by time of use.
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12.18 Agreed capacity charges
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Depends on extent to which costs are driven per-kW, and any modifiers for operational flexibility provided
- Depends on ability to limit volatility- Limited cost-reflectivity so not appropriate for a FLC
4 - Provide a level
playing field for all
network users
- Depends on extent to which costs are driven per-kW, and any modifiers for operational flexibility provided
- Depends on ability to limit volatility- Limited cost-reflectivity so will not create a level playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Particularly well suited as an option for incentivising user investment decisions
- If relatively predictable years in advance and viewed as stable, which this might not be
- Does not provide any operational dispatch price signal; therefore agreed capacity charges would need to be combined with some other
mechanism (e.g. Balancing Mechanism) to provide operational dispatch incentives
'- Not effective as not cost-reflective
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Depends on extent to which costs are driven per-kW, and any modifiers for operational flexibility provided
- Depends on ability to limit volatility- Lack of cost-reflectivity means inappropriate risk allocation
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- If incremental future network investment is driven by user capacity, then this could provide an effective cost reflective price signal
- It may be appropriate to reflect that different types of user (of the same agreed capacity) may cause different incremental future costs to the
network
- Not fully cost-reflective and hence less efficient
- Dependent on tariff design and time of use signals, but unlikely to be cost reflective if a flat rate is applied to agreed capacity in all time periods
1 - Efficiently meet
the essential service
requirements of
network users
- Users can obtain certainty by contracting in advance for the capacity (or 'access') they require
- Values availability of the network
7 - Support efficient
network development
- Incentivises users to agree appropriate capacities, so the network business obtain information regarding the future investment decisions of
users
8 - Be Practical- Easily applied to larger users with bilateral connection agreements
- Could be used with generators and load users grouped together- Difficult to apply to smaller users who do not have bilateral connection agreements (unless operating as a group)
9 - Be Proportionate - Provides means of paying for 'availability' of the network even where generation is "behind the meter."
Assessment Criteria
Tariff Elements - Agreed Capacity Charges
Charges levied in respect of a user’s agreed capacity with the network operator. Agreed capacities are generally specified in bilateral connection agreements, and as such are only in place for larger users.
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12.19 Peak demand charges
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Likely to give a good FLC - Depends on the specific definition of "peak", whether this results in stable, predictable (useful) tariffs
4 - Provide a level
playing field for all
network users
- Likely to be more cost-reflective and hence provide a level-playing field - Depends on the specific definition of "peak", whether this results in stable, predictable (useful) tariffs
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- More cost-reflective
- Likely to be difficult (particularly for small users) to respond to as requires a high level of visibility of usage at all times in order to identify and
reduce peak usage
- Can be harder to predict
- Balancing mechanism approach likely to be more effective for providing operational signals
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- More cost-reflective and hence better at allocating risk - Depends on the specific definition of "peak", whether this results in stable, predictable (useful) tariffs
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st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Can be cost reflective if costs are driven by user’s peak demands at certain times
- More cost-reflective and hence appropriate for an FLC- Network costs are driven by network peaks rather than individual user's peaks
1 - Efficiently meet
the essential service
requirements of
network users
- Encourages the right behaviour and cost reflective of need.
' Requires sufficiently predictable windows of charge
7 - Support efficient
network development
- Encourages right amount of capacity to be bought
- Depends on extent users can respond and appropriate flexibility can be purchased
8 - Be Practical - Easily applied to users with HH metering - Cannot be applied to users with NHH metering
9 - Be Proportionate
Assessment Criteria
Tariff Elements - Peak Demand Charges
Charges for peak usage, i.e. for half hourly metered users the usage in the peak half hour.
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12.20 Reactive power charges
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Depends on extent to which costs are driven per-kVA or per-kVAr, and any modifiers for operational kVAr flexibility provided (to T or D!)
4 - Provide a level
playing field for all
network users
- Depends on extent to which costs are driven per-kVA or per-kVAr, and any modifiers for operational kVAr flexibility provided (to T or D!)
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Can be predictable for larger users with sophisticated understanding, and action can be taken through up front investment in power factor
correction equipment- Smaller user unlikely to be aware of reactive power or be able to make changes to respond
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Depends on extent to which costs are driven per-kVA or per-kVAr, and any modifiers for operational kVAr flexibility provided (to T or D!)
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Can be cost reflective if proportional to the extent to which network costs and/or benefits are driven by reactive power usage beyond the need
for greater capacity- (Must add a modification or exemption for users which are providing a Reactive Power service)
1 - Efficiently meet
the essential service
requirements of
network users
- Supports market for reactive power service providers
7 - Support efficient
network development
- Depends on extent users can respond and appropriate flexibility can be purchased
- The control of reactive power flows is becoming increasingly important at distribution (to avoid voltage rise); effective price signals for reactive
power (including incentivising reactive power flows where needed) could support efficient development of the network
8 - Be Practical - Easily applied to users with four quadrant metering (measuring real import/export and reactive import/export - generally larger users) - Impossible to apply for users without four quadrant metering
9 - Be Proportionate
Assessment Criteria
Tariff Elements - Reactive Power Charges
Charges for usage of reactive power, reflecting the difference between actual power (in kW) and apparent power (in kVA), and where the two diverge due to poor power factor which drives the need for increased network capacity.
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12.21 Unrestricted unit rates
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Limited cost-reflectivity so not appropriate for a FLC
4 - Provide a level
playing field for all
network users
- Limited cost-reflectivity so will not create a level playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Simple for users to understand - Only action which can be taken is to reduce overall usage - moving usage to other times has no impact on charges faced
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Lack of cost-reflectivity means inappropriate risk allocation
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Risks over-valuing lower overall usage and under-valuing reduced usage at peak
- Not cost-reflective for FLC UoS charges
- Probably the least cost-reflective
1 - Efficiently meet
the essential service
requirements of
network users
7 - Support efficient
network development
8 - Be Practical - Easily applied to all users
9 - Be Proportionate
Assessment Criteria
Time of Use Options - Unrestricted Unit Rates
A charge which applies to every unit used (or capacity taken) in any time period.
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12.22 Static time of use unit rates
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Depends upon the bands used, but is a versatile option to allow cost-reflective FLC Time periods might vary in different parts of the network
4 - Provide a level
playing field for all
network users
- Depends upon the bands used, but is a versatile option to create level-playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Prices and time periods are known in advance, so users can respond to them
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- More cost-reflective and hence better at allocating risk
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- May be useful to signal low cost network periods to demand users, such as low/zero locational network charges overnight
- To the extent that usage of the network in fixed time periods drives network costs and/or benefits, static time of use charges can be cost-
reflective
- May incentivise inefficient operational dispatch decisions relating to periods of constraint - this is because periods of system stress are a
function of outturn factors such as weather, demand, market events
- If network investment is driven by user capacity, then a price signal which aims to affect user operational dispatch at times of peak demand may
fail to be cost reflective of incremental future network investment
- If set globally, may encourage ‘wrong’ behaviours i.e. increased generation in generation dominated areas etc.
- Static TOU is not reflective of operational dispatch costs especially as these are increasingly driven by the weather
1 - Efficiently meet
the essential service
requirements of
network users
7 - Support efficient
network development
- In this situation, the network operator would be a price setter and volume taker which may make it difficult to manage the operation of the
network because they cannot control how much capacity will respond to the price signal, or at what location
8 - Be Practical - Easily applied to users with HH metering- Cannot be applied to users with NHH metering
- Creates cliff-edges which may be a particular risk with automation
9 - Be Proportionate
Assessment Criteria
Time of Use Options - Static Time of Day Unit Rates
Charges which vary by time of day with time bands fixed throughout the year (akin to the existing red, amber and green unit rates for HH settled distribution connected users at LV and HV).
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12.23 Critical peak pricing
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Depends upon the bands used, but is a versatile option to allow cost-reflective FLC
4 - Provide a level
playing field for all
network users
- Depends upon the bands used, but is a versatile option to create level-playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Assuming the critical peak period and price are known in advance, users can respond easily- May clash and distort response to other price signals which are also designed to provide price signals which may be associated with periods of
network stress
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- To the extent which network usage in the critical peak period drives network costs and/or benefits, critical peak prices can be cost-reflective
- Peak demand charging on its own would fail to provide an effective price signal for generation dominated zones where network investment is
required to mitigate constraints caused by generation
- If network investment is driven by user capacity, then a price signal which aims to affect user operational dispatch at times of peak demand may
fail to be cost reflective of incremental future network investment
1 - Efficiently meet
the essential service
requirements of
network users
7 - Support efficient
network development
- In this situation, the network operator would be a price setter and volume taker which may make it difficult to manage the operation of the
network because they cannot control how much capacity will respond to the price signal, or at what location
8 - Be Practical - Easily applied to users with HH metering
- Cannot be applied to users with NHH metering
- Capacity drivers and investment drivers need to be identified and these may change the peaks as this is not a static function. Is this set ex-
ante? There may be linkages ot 'managed connections'
9 - Be Proportionate
Assessment Criteria
Time of Use Options - Critical Peak Pricing (CPP)
Charges which vary by time of day with a narrow peak band in which the cost per unit is significantly higher (akin to the existing ‘super-red’ period for distribution connected users at EHV which applies only to a relatively small number of time periods in the year, and at the extreme HH TNUoS
triad charges which have a very narrow ‘critical peak’ period).
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12.24 Variable time of use rates
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Potentially can be very cost-reflective
4 - Provide a level
playing field for all
network users
- Favours users with smart technology which can respond to short-term price signals automatically
- Potentially a good option but complexity may create barriers
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Potential for very effective response for users with smart technology
- May be difficult for some users to respond to, particularly smaller demand users
- May clash and distort response to other price signals which are also designed to provide price signals which may be associated with periods of
network stress
- Increased cost-reflectivity may make this less predictable
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- More cost-reflective and hence better at allocating risk - If some users are not exposed ot tariff, this increases the volatility/risk to others
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- May tend to provide a more cost reflective operational dispatch price signals than static TOU tariffs
- More cost-reflective and hence appropriate for an FLC
- If network investment is driven by user capacity, then a price signal which aims to affect user operational dispatch at times of peak demand may
fail to be cost reflective of incremental future network investment
1 - Efficiently meet
the essential service
requirements of
network users
7 - Support efficient
network development
- In this situation, the network operator would be a price setter and volume taker which may make it difficult to manage the operation of the
network because they cannot control how much capacity will respond to the price signal, or at what location
8 - Be Practical- May be challenging to calculate real time dynamic tariffs
- Likely to be more difficult to implement
9 - Be Proportionate - Would need ot opt in
- As a method of providing an operational dispatch incentive, it may be disproportionate and detrimental to expose all users to dynamic TOU
tariffs, even if many of those users cannot respond to them. Also disproportionate in comparison to alternative options for providing high
resolution real time dispatch signals, such as a Balancing Mechanism approach which can provide a price signals for those users who choose to
participate in the BM and therefore can respond to them.
Assessment Criteria
Time of Use Options - Variable Time of Day
Charges which vary (potentially up to real time) by time period depending on the level of demand at the time (TNUoS triad charges have some features of this, in that the time periods to which the £/kW unit rate will apply are variable based on the times of peak demand, albeit the rates
themselves are fixed at the start of each year).
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12.25 Inclining block rates
Advantages Disadvantages
2 - Optimise Capacity
Allocation
4 - Provide a level
playing field for all
network users
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Smaller users may find it difficult to monitor when their usage is remaining within the 'lower' block in order to take action to avoid going over
the threshold into the 'higher' block
- May clash and distort response to other price signals which are also designed to provide price signals which may be associated with periods of
network stress
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Not cost reflective - an increment of usage does not impose fundamentally different costs if driven by a high usage user than by a low usage
user
1 - Efficiently meet
the essential service
requirements of
network users
- Meets service requirements of low usage users at low cost, whilst exposing higher usage users (e.g. EV owners) to higher costs- Dependent on the level of the rising blocks - risk of penalising large households compared to smaller households for the same type of
'essential' usage
7 - Support efficient
network development
8 - Be Practical - Easily applied to users with HH metering - Cannot be applied to users with NHH metering
9 - Be Proportionate
Assessment Criteria
Time of Use Options - Inclining Block Rates
Under this option a lower unit rate would be applied to usage below a certain threshold, and a higher unit rate to usage above this threshold (note – more than two ‘blocks’ could be used).
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Appendix Seven– Advantages and disadvantages of Charging Model Options as Expressed by Task Force
members
12.26 Transport model
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Gives no indication of capacity simply allocates costs of maintaining the status quo
- Does not include cost based on absolute cost impact
4 - Provide a level
playing field for all
network users
- Lack of locational signals results in all user actions being given the same cost signal regardless of the actual cost and/or benefit derived
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Likely to result in stable prices - Lack of pointed locational signal
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Lack of cost-reflective charges means that risk will not be appropriately allocated.
- Requires locational and constraint costs to be reflected though other means e.g. deeper connection boundary
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Likely to result in stable prices
- Price changes are predictable
- Lack of pointed locational signal
- Does not provide cost-reflective signals or charges
- Depends how granular/nodal this is worked out at. At a granular level, this can become a disadvantage: backwards-looking tariffs reflect lumpy
investment as steep volatility, potentially driven by other user's new connections!
1 - Efficiently meet
the essential service
requirements of
network users
- Price signal for flexible generators muted
- Lack of cost-reflective charges means that users do not face appropriate incentives and hence overall network likely to be very inefficient.
7 - Support efficient
network development- Gives no signal as to how a network develops and so no information to the network operator or user for better use of the network
8 - Be Practical - Likely slightly more complex than existing LV and HV but simpler than existing EHV and TNUoS - Whilst a simpler approach, not practical to use a model which has such disadvantages
9 - Be Proportionate - Should be considered for sunk cost recovery - i.e. by the TCR
Assessment Criteria
Charging Model Options - Transport Model
Cost of importing or exporting energy through an existing network
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12.27 Expansion model
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Signals areas of low and/or high capacity
- Relatively predictable, magnitude of changes low during CM timescales
- Does not recognise specific reinforcement costs of addressing capacity constraints
- Only provides relative locational signals, not absolute cost signals which is likely to distort the market and impact competition
4 - Provide a level
playing field for all
network users
- Symmetric treatment of demand and generation- Symmetric treatment ignores engineering factors related to fault-level reinforcement etc.
- Only provides relative locational signals, not absolute cost signals which is likely to distort the market and hence not create a level-playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Should be possible for an expansion model to result in reasonably stable prices
- Use of up front assumptions (expansion constant and fixed asset costs) reduces the need for network operator to make internal assumptions
and so increases transparency
- Avoids attributing specific network investments to specific network users.
- Can provide stable price signals but to the detriment of cost-reflectivity and hence this will not be effective
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Avoids attributing specific network investments to specific network users.- Lack of cost-reflective charges means that risk will not be appropriately allocated.
- Requires locational and constraint costs to be reflected though other means e.g. deeper connection boundary
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st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Should be possible for an expansion model to result in reasonably stable prices
- Use of up front assumptions (expansion constant and fixed price per km) reduces the need for network operator to make internal assumptions
and so increases transparency
- Provides cost reflective price signal assuming cost of expansion is reflected by the weighted cost of existing network
- Average costs do not reflect the actual cost of reinforcement at any given location - but this could be a somewhat localised signal by design
- Does not provide cost-reflective signals or charges
1 - Efficiently meet
the essential service
requirements of
network users
- Lack of cost-reflective charges means that users do not face appropriate incentives and hence overall network likely to be very inefficient
7 - Support efficient
network development- Symmetric treatment of demand and generation - Symmetric treatment of demand and generation ignores engineering factors related to fault-level reinforcement etc.
8 - Be Practical - More complex than existing LV and HV, simpler than existing EHV, complexity as per status quo for TNUoS- Whilst a simpler approach, not practical to use a model which has such disadvantages
- Assumes no constraint assumption/capacity
9 - Be Proportionate - Unable to judge proportionality at this stage
Assessment Criteria
Charging Model Options - Expansion Model
Levelised cost of future network based on a weighted average of the existing network
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12.28 Remaining headroom model
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Signals areas of low and/or high remaining capacity and scale of increasing capacity
- Increased recognition of reinforcement cost
- More closely linked to actual network and required costs/savings due to users actions and hence less distortion to competition
- Predictability of signal reduced, parties cannot effectively make investment decisions
- Sharing factor important - if secondary actions affect the primary decision to locate then costs are hard to predict. i.e. 'sawtooth pattern'
4 - Provide a level
playing field for all
network users
- Demand treatment highly reflective of security of supply standards
- Likely to provide a better FLC for demand- Generation not subjected to a locational signal (due to no underlying security of supply standard)
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Site specific (but rule based) reinforcement costing
- Most cost-reflective approach
- Subject to saw-tooth price increases or year to year volatility, with a user's charges often influenced by the actions of other users in the same
location
- Sacrifices predictability
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Most cost-reflective approach means risk likely to be best allocated
- Attributes specific network investments to specific network users which may over-expose individual users to the risk that reinforcement is
required
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Highly cost-reflective by exposing users to the cost and/or benefit of network reinforcements which their behaviour has the potential to drive
and/or avoid
- Low predictability, reduces ability of participant to properly account for costs in long-medium term. Can lead to inefficient investment decisions
which increases costs in short-term constraint management
- If set nodally or zonally, then existing user's tariff driven by OTHER users' behaviour - wholly un-reflective - and ultimately all users will just see
this as a source of volatility, unless individual tariffs can be locked-in
1 - Efficiently meet
the essential service
requirements of
network users
- Most cost-reflective approach likely to be most efficient- Penalising tariffs in constrained areas - will discourage new providers of flexibility (only contracted to relieve the worst excess, thereby taking
the network to just full, hence likely to incur a high tariff related to zero remaining headroom)
7 - Support efficient
network development
- Demand treatment highly reflective of security of supply standards
- Taking account of spare capacity on the network can lead to more efficient locational decisions- Generation not subjected to a locational cost signal (due to no underlying security of supply standard)
8 - Be Practical- Status quo for EHV distribution charging
- Should be practical to use across all voltages- Significantly more complex than existing LV and HV, and more complex for TNUoS
9 - Be Proportionate - Unable to judge proportionality at this stage
Assessment Criteria
Charging Model Options - Remaining Headroom
Cost of addressing the next constraints in accordance with today’s design standards
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12.29 500MW or probabilistic model
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Generalised model reflective of current engineering practice - No locational element to charges so not specific to any site
4 - Provide a level
playing field for all
network users
- Lack of locational signals results in all user actions being given the same cost signal regardless of the actual cost and/or benefit derived
- No locational signal means charges are not cost-reflective and hence likely to be distorted which does not create a level-playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Likely to result in stable prices
- Price changes are predictable
- Lack of pointed locational signal
- Stable prices but no cost-reflectivity
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Lack of cost-reflective charges means that risk will not be appropriately allocated
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Recognises the cumulative effect of multiple customers connecting to the network
- Price changes are predictable
- Limited locational signal
- Likely to require assumptions from the network operators when operating the model
- Does not provide locational cost-reflective signals or charges
1 - Efficiently meet
the essential service
requirements of
network users
- Price signal for flexible generators muted
- Lack of cost-reflective charges means that users do not face appropriate incentives and hence overall network likely to be very inefficient
7 - Support efficient
network development- Results in stable prices which are likely to result in predictable user responses
- Limited location signal
- Lack of cost-reflective charges means that users do not face appropriate incentives and hence overall network likely to be very inefficient
- Outdated, therefore unfit for actively managed networks
8 - Be Practical- Relatively easy to implement - status quo at HV and LV, simplification for EHV and TNUoS
- Over-simplification means this is relatively easy to implement
- Draws on propriety data/engineering approaches
- No on builds 500MW increments, not true to life
- Excludes reinforcement/reinstatement
- Assumes new assets each year
9 - Be Proportionate - Unable to judge proportionality at this stage
Assessment Criteria
Locational Signals - 500MW Model/Probabilistic Model
Cost allocation' model
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12.30 DC Load Flow Investment Cost Related model
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Signals areas of low and/or high capacity against approximation of planning standards
- Use of DC Load Flow is a tool to simplify the study of a network - reflective for an interconnected system but less reflective of physical power
flows on certain types of networks
- Too far removed from dynamic operational model - flexibility providers operationally supporting the network may be modelled here as causing
issues in the limited snapshot model, producing a disproportionally high tariff
- Only provides relative locational signals, not absolute cost signals which is likely to distort the market and impact competition
4 - Provide a level
playing field for all
network users
- Symmetric treatment of demand and generation (in TNUoS)
- Symmetric treatment ignores engineering factors related to fault-level reinforcement etc.
- Can it account for different operational profiles?
- Lack of absolute cost signal means distortion likely which does not create a level playing field
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Use of up front assumptions (expansion constant and fixed asset costs) reduces the need for network operator to make internal assumptions
and so increases transparency
- Avoids attributing specific network investments to specific network users
- Potential to result in volatile prices (particularly with LRIC approach), with a user's charges often influenced by the actions of other users in the
same location
- Relatively short term predictability but still limited in the longer term and is still not fully cost-reflective
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Lack of cost-reflective charges means that risk will not be appropriately allocated
- T and EHV should design with one another otherwise risk not shared
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st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- More price reflective than transport model or 500MW model
- Relatively predictable changes based on changes in use of network, allows parties to change behaviour
- Average costs do not reflect the actual cost of reinforcement at any given location.
- Use of DC Load Flow is a tool to simplify the study of a network - reflective for an interconnected system but less reflective of physical power
flows on certain types of networks
- Unreflective of differing operational profiles
1 - Efficiently meet
the essential service
requirements of
network users
- Lack of cost-reflective charges means that users do not face appropriate incentives and hence overall network likely to be very inefficient.
7 - Support efficient
network development- Symmetric treatment of demand and generation
- Symmetric treatment ignores engineering factors related to fault-level reinforcement etc.
- Lack of cost-reflective charges means that users do not face appropriate incentives and hence overall network likely to be very inefficient
8 - Be Practical- Status quo for (some) EHV distribution charging and TNUoS
- LRIC used in conjunction with local circuits to increase specificity of tariffs
- Significantly more complex than existing LV and HV
- Questioned the limit to the extent of additional increments
- ICRP and LRIC should not be grouped
9 - Be Proportionate - Unable to judge proportionality at this stage
Assessment Criteria
Locational Signals - DC Load Flow Investment Cost Related/Long Run Incremental Cost
Incremental model
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12.31 Forward cost pricing model
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Signals areas of low and/or high remaining capacity and scale of increasing capacity
- Allocates prices to network groups rather than nodes - so can optimise allocation between groups but not inter-group
- More closely linked to actual network and required costs/savings due to users actions and hence less distortion to competition
4 - Provide a level
playing field for all
network users
- Demand treatment highly reflective of security of supply standards
- Whilst likely to provide volatile signals, this does give the most cost-reflective approach
- Generation not subjected to a locational signal (due to no underlying security of supply standard)
- More cost-reflective signal for demand is better, but approach needs to be adapted to provide similar for generation
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Site specific (but rule based) reinforcement costing
- Whilst likely to provide volatile signals, this does give the most cost-reflective approach
- Subject to saw-tooth price increases or year to year volatility, with a user's charges often influenced by the actions of other users in the same
location
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Most cost-reflective approach means risk likely to be best allocated
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Highly cost-reflective by exposing users to the cost and/or benefit of network reinforcements which their behaviour has the potential to drive
and/or avoid.
- High volatility and low predictability in approach reduces the ability of network users to respond to signals
- Tariffs could be driven by other users
1 - Efficiently meet
the essential service
requirements of
network users
- Most cost-reflective approach likely to be most efficient - Volatility unwelcome to most users
7 - Support efficient
network development- Demand treatment highly reflective of security of supply standards - Generation not subjected to a locational signal (due to no underlying security of supply standard)
8 - Be Practical - Status quo for (some) EHV distribution charging - Significantly more complex than existing LV and HV, and more complex for TNUoS
9 - Be Proportionate - Unable to judge proportionality at this stage
Assessment Criteria
Locational Signals - Forward Cost Pricing
Contingency model
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12.32 Single model across transmission and distribution
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Avoids distortionary investment incentives which may be simply an artefact of different charge calculation models
- May not reflect different planning standards or engineering practice etc.
- Whilst theoretically this would provide a harmonised approach, it may lead to too much complexity in the model
4 - Provide a level
playing field for all
network users
- Avoids distortionary investment incentives which may be simply an artefact of different charge calculation models - May not reflect different planning standards or engineering practice etc.
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- Allows users to make comparable decision between T&D investments
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Comparable costs allows more efficiently allocate agreements to generation, reducing cost to consumers and reducing risk of stranded assets
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Avoids distortionary investment incentives which may be simply an artefact of different charge calculation models
- May not reflect different planning standards or engineering practice etc.
- Principles of structure should align but not necessarily weighting between different tariff components across the network.
- Shouldn’t be a target proportion on fixed/unit.
1 - Efficiently meet
the essential service
requirements of
network users
7 - Support efficient
network development- Avoids distortionary investment incentives which may be simply an artefact of different charge calculation models - May not reflect different planning standards or engineering practice etc.
8 - Be Practical
- Requires significant work to achieve development of a common model which appropriately reflects the attributes of all transmission and
distribution networks which have different planning and construction standards
- Need harmonised connection boundary/user commitment
- Requires governance changes to codes
- Need to standardise pricing structure, principles and assumptions
9 - Be Proportionate - Benefits may be achievable without the need for a common model
Assessment Criteria
Single model across all voltage levels
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12.33 Transmission and distribution charging models different but with common assumptions
Advantages Disadvantages
2 - Optimise Capacity
Allocation
- Aligns models
- Aligned models are less likely to create distortions between networksSome discontinuities will remain
4 - Provide a level
playing field for all
network users
- Aligns models
- Could be different models of the same type- Some discontinuities will remain
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
- More likely to allow appropriate comparison between connection and use of network at different voltages
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Different allocation of risk in Scotland compared to England, not justified by the underlying engineering/physics
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Aligns models
- Common assumptions e.g. for growth- Some discontinuities will remain
1 - Efficiently meet
the essential service
requirements of
network users
7 - Support efficient
network development- Aligns models - Some discontinuities will remain
8 - Be Practical - May be possible to agree common assumptions more easily than it would be possible to achieve a common model- Alignment of assumptions could be challenging given the different engineering standards which apply
- Need to consider whether this requires harmonised connection boundary/user commitment
9 - Be Proportionate- Potential to deliver benefits of commonality without the need for full alignment of charging assumptions which relate to different engineering
standards- Results in some distortion
Assessment Criteria
T&D charging model different but with common assumptions
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12.34 Different models across transmission and distribution
Advantages Disadvantages
2 - Optimise Capacity
Allocation- Models can more closely reflect different planning standards or engineering practice etc.
- Potential for distortionary investment incentives which may be simply an artefact of different charge calculation models
- Risk that ongoing mods could lead to divergence over time
4 - Provide a level
playing field for all
network users
- Models can more closely reflect different planning standards or engineering practice etc.- Potential for distortionary investment incentives which may be simply an artefact of different charge calculation models
- Risk that ongoing mods could lead to divergence over time
5 - Provide effective
network user price
signals, i.e. price
signals which can be
reasonably
anticipated by a user
with sufficient
confidence to allow
them to take action
6 - Appropriately
allocate risk between
individual network
users and the wider
body of users
- Different allocation of risk in Scotland compared to England, not justified by the underlying engineering/physics
Co
st R
efle
ctiv
ity
3 - Ensure that price
signals reflect the
incremental future
network costs and
benefits that can be
allocated to and
influenced by the
actions of network
users
- Models can more closely reflect different planning standards or engineering practice etc.- Potential for distortionary investment incentives which may be simply an artefact of different charge calculation models
- May be more approrpaite to split by voltage tiers not Transmission and Distirbution
1 - Efficiently meet
the essential service
requirements of
network users
7 - Support efficient
network development- Models can more closely reflect different planning standards or engineering practice etc. - Potential for distortionary investment incentives which may be simply an artefact of different charge calculation models
8 - Be Practical - Avoids the need for complex work to align charging assumptions which relate to different engineering standards - Modelling differences would require enduring fix and not just interim methods
9 - Be Proportionate - Resulting distortion
Assessment Criteria
Different charging models across T&D
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Appendix Eight – Users’ and Providers’ Perspectives
12.35 Large, Transmission-connected Generation Users:
Depth: Sufficient access the National Balancing Point in order to allow access to
and trade in national energy markets. Distributed assets affect the flows on the
transmission network irrespective of whether they choose to trade their power
locally, or nationally.
Lifespan: Some would prefer choice regarding fixed duration rights including long-
term rights (e.g. number of years) and short-term rights (e.g. Settlement Periods),
while others would prefer evergreen rights with no fixed duration and no optionality
regarding Settlement Periods. Either approach is crucial with access rights
matched with liability to pay tariffs for the life of the asset. This is particularly
important to ensure generation can participate in the Capacity Market.
Time of Use/seasonal: Some would prefer access choices, to vary their charge
based on varying their access capacity at different times (within day, or within
year), while others would prefer less optionality, so charges would instead be
based on flat contracted access capacity across the whole year. Care should be
taken in the design of access rights and charges to avoid the risk that optionality
regarding the timing of access capacity may enable users to arbitrage between
tariffs to avoid paying cost-reflective charges, or to crowd out access capacity of
other users at particular times. There should be clear locational symmetry (same
signal for demand and generation). Also important to ensure charges are practical
Financial firmness: Some prefer choice between financially firm or non-firm
rights, while others prefer no optionality, such that all users should have financially
firm access. Firm access would result in financial compensation if network is
unavailable and the ability to hedge risk. Also noting that having the choice of
financially non-firm connections may create distortions in the Balancing
Mechanism.
Physical firmness: Right to flow on and off the network subject to physical
capacity (however defined) and physical connection to the system. Network
companies to maintain availability with standards (e.g. 99.99% reliability) with
measures taken to avoid gaming if the choice of physically non-firm connections
are offered
Standardisation of access choices: Level playing field with same rights for all
and same cost-reflective liabilities to pay for network (e.g. capacity charges/kW).
12.36 Distribution-connected Generation and Storage Users:
Depth: Access to the National Balancing Point in order to trade across GB
markets, with measures taken to levy tariffs across assets in front of and behind
the meter. Distributed generation may also value ability to contract directly with
local demand in some circumstances.
Lifespan: Choice in long-term rights (e.g. number of years) and short-term rights
(e.g. Settlement Periods); including very long-term rights (e.g. 40 years or more)
Time of Use/seasonal: Time of use access rights that can be matched to the
expected profile of the generation to allow optimisation between access rights and
export.
Financial firmness: Choice of financially non-firm rights are valued for generation
able to flex
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Physical firmness: Where assets are providing balancing services, physically
firm connections will be necessary (at the very least for those periods of delivery)
Standardisation of access choices: Increases transparency and speeds up
connection process.
12.37 Community Energy Users:
Depth: Choice of depth of access, including the option for only local access to
balance local supply and demand or share network access between a number of
local users
Lifespan: Choice in long-term rights (e.g. number of years) favouring longer-term
access
Time of Use/seasonal: Clear locational symmetry (same signal for demand and
generation)
Financial firmness: Choice of financially firm or non-firm rights; including, for
example, firm connection to the local LV network but non-firm beyond this
Physical firmness: Right to flow on and off the network subject to physical
capacity (however defined) and physical connection to the system. Network
companies to maintain availability with standards (e.g. 99% reliability)
Standardisation of access choices: Access choices that recognize value of
matching supply and demand locally and leasing network choices such as annual
fixed LV usage charge for local energy /local network leasing structure.
12.38 Large Demand Users:
Depth: For most, full access to the UK network including the National Balancing
Point to trade on the wholesale market. Future peer-to-peer trading models that
make use of industrial loads may not trade on the wholesale market. It remains
possible that such models may not require full network access but this remains to
be fully tested
Lifespan: For most, evergreen access rights will be required. There is likely to be
minimal demand for less than evergreen rights as anything shorter than evergreen
(e.g. 10 years or 20 years) would create very high risks for large sites
Time of Use/seasonal: Large variety of choice desired regarding limits on
export/import during a season or other specific time periods for commensurate
reduction in network charges for those larger users who can predict usage patterns
over the year. This choice needs to be balanced with ensuring that it remains
simple for users to engage in. Examples of where choice could be useful include
holiday camps, shift patterns of factories, factories with planned maintenance in
the summer and flexible water utility pump stations
Financial firmness: For most, financially firm connections at least and physically
and financially firm as security of supply is crucial in many sectors such as
refineries, hospitals other large industrial processing sectors. Some large users
may be able to accept financially non-firm connections. ITOs, IDNOs and private
networks may not be able to accept non-firm in any context. Compensated buy-
back of any unused capacity is essential
Physical firmness: For almost all, 99.99% reliability is essential and some will
need to invest in Uninterruptible Power Supply even above this standard.
However, less than this may become more viable as the use of on-site generation
and storage grows
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Standardisation of access choices: As far as possible, a more aligned approach
to connection boundary between transmission and distribution is desirable.
Access choices show clear financial value where demand offsets local generation
and supports system balancing such as managing long-term constraints and nodal
balancing (e.g. demand connecting in a generation dominated area).
12.39 Domestic Users:
Depth: Full access to the UK network, especially for vulnerable users to benefit
from energy market economies of scale. Some domestic users may also value
direct access to local generation.
Lifespan: Evergreen access rights
Time of Use/seasonal: If put in place, any time of use or seasonal access choices
would require a level of automation and network company access to user data and
would need to be simple to understand. Users need to be able to respond to these
signals. Protections need to be in place for vulnerable users (especially those who
cannot respond to signals - health reasons, for example). New property owners
should not be disadvantaged due to previous owners/ developers access choice.
Financial firmness: Financially firm access.
Physical firmness: 99.99% reliability is essential. Non-firm options are unlikely to
be useful without automation. A choice of access options could cause users to
choose cheaper access which doesn't meet their requirements. This would create
a two-tier connection option for domestic users where those that can afford access
pay for it and those that can't might not be able to. New property owners should
not be disadvantaged due to previous owners/ developers access choice.
Standardisation of access choices: Physical firmness up to service fuse
capacity is currently expected but a core entitlement with choice to pay more for
extra capacity might be possible. New users should pay their fair share of access
and upgrades to the local network to protect existing users. For example, local grid
upgrades due to new electric vehicle connections may not benefit existing users
as their access arrangements should not have changed. Any choices must be
simple for users to understand at domestic level.
12.40 Electricity System Operator:
Depth: Choice for users to have access to the whole system and each market
(including ancillary service provision). Network companies need to have certainty
of delivery of services when called upon, irrespective of voltage level.
Lifespan: User choice as the default – as long as considered in tandem with the
level of user commitment required
Time of Use/seasonal: More choice rather than less as the default, but
consideration needs to be given to how network companies plan and operate the
system. The more choice, the more complex and volatile the signals will be and
less diversity can be assumed when allocating capacity
Financial firmness: User choice of firm/non-firm financial rights and financial
compensation if network is unavailable
Physical firmness: User choice of firm/non-firm physical rights. Network
companies will continue to require certainty of dispatch
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Standardisation of access choices: Network users having consistent choice in
the access products and be exposed to similar costs to reflect these rights (e.g.
higher cost for firm access rights).
12.41 Distribution Network Operators:
Depth: Choice for users for firm access up to the nearest Primary Substation,
primary, bulk supply point, grid supply point and where required the transmission
network to supply energy from distribution-connected assets, with future rights to
the transmission network to be procured possibly though a new ‘distribution
transmission entry capacity’ product
Lifespan: User choice to contract based on short-term (Settlement Period, day or
month) and long-term (multi-year) rights
Time of Use/seasonal: User choice to contract based on time of use (e.g. non-
peak times only) or seasonal (e.g. winter period from November to March only)
rights
Financial firmness: User choice to contract based on non-firm financial rights
(without compensation) or firm financial rights (with compensation during
constraint events)
Physical firmness: Provide firm (N-1 or greater) and non-firm options (N-0) or
physical connection arrangements to ensure users have the physical ability to
export/import energy on and off the network (subject to their agreed capacity and
having appropriately funded the agreed connection arrangements)
Standardisation of access choices: Standard access rights for all, subject to
availability and users’ willingness to pay.